ML073240753
| ML073240753 | |
| Person / Time | |
|---|---|
| Site: | Vogtle  |
| Issue date: | 12/31/1996 |
| From: | Huddlestun P F, Summerour J H State of GA, Dept of Natural Resources, State of GA, Environmental Protection Div |
| To: | Office of Nuclear Reactor Regulation |
| References | |
| NL-07-2097 | |
| Download: ML073240753 (98) | |
Text
THE LITHOSTRATIGRAPHIC FRAMEWORK OF THE UPPERMOST CRETACEOUS AND LOWER TERTIARY OF EASTERN BURKE COUNTY, GEORGIA Paul F. Huddlestun and Joseph H. Summerour GEORGIA DEPARTMENT OF NATURAL RESOURCES Lonice C. Barrett, Commhioner ENVIRONMENTAL PROTECTION DIVISION Harold F. Reheis, Director GEORGIA GEOLOGIC SURVEY William H. McLemore, State Geologist Atlanta 1906 Bulletin 127 THE LITHOSTRATIGRAPHIC FRAMEWORK OF THE UPPERMOST CRETACEOUS AND LOWER TERTIARY OF EASTERN BURKE COUNTY, GEORGIA Paul F.Huddlestun and Joseph H.Summerour GEORGIA DEPARTMENT OF NATURAL RESOURCES Lonice C.Barrett, Commissioner ENVIRONMENTAL PROTECTION DIVISION Harold F.Reheis, Director GEORGIA GEOLOGIC SURVEY William H.McLemore, State Geologist Atlanta 1996 Bulletin 127 ABSTRACT One new formation, two new members, and a reclefhition of an established lithostratigraphic unit are formally introduced here. The Oconee Group is formally recognized in the Savannah River area and four South Carolina Formations not previously used in Georgia by the Georgia Geologic Survey are recognized in drn Burke County. The Still Branch Sand is a new formation and the two new members are the Bennock Millpond Sand Member of the Still Branch Sand and the Blue Bluff Member of the Lisbon Formation. The four South Carob formations recognized in eastern Burke County include the Steel Creek Formation and Snapp Formation of the Oconee Group, the Black Mingo Formation (undifferentiated), and the Congaree Formation. The Congaree Formation and Still Branch Sand are considered to be lithostratigraphic components of the Claiborne Group.
The Congaree Formation is included in the Claiborne Group because it extends westward to the Chattahoochee River area of Georgia and Alabama, and perhaps farther west into Alabama. In this area, the Congaree has been called the Tallahatla Formation for many years and the Alabama and w-rn Georgia "Tallahatla" is an essential formation of the Claiborne Group. The age and correlation of all of the lithostratigraphic unita are discussed.
In addition, the Pen Branch fault is recognized in the vicinity of Hancock Landing in eastern Burke County. ABSTRACT One new formation, two new members, and a redefinition of an established lithostratigraphic unit are formally introduced here.The Oconee Group is formally recognized in the Savannah River area and four South Carolina Formations not previously used in Georgia by the Georgia Geologic Survey are recognized in eastern Burke County.The Still Branch Sand is a new formation and the two new members are the Bennock Millpond Sand Member of the Still Branch Sand and the Blue Bluff Member of the Lisbon Formation.
The four South Carolina formations recognized in eastern Burke CountY include the Steel Creek Formation and Snapp Formation of the Oconee Group, the Black Mingo Formation (undifferentiated), and the Congaree Formation.
The Congaree Formation and Still Branch Sand are considered to be lithostratigraphic components of the Claiborne Group.The Congaree Formation is included in the Claiborne Group because it extends westward to the Chattahoochee River area of Georgia and Alabama, and perhaps farther west into Alabama.In this area, the Congaree has been called the Tallahatta Formation for many years and the Alabama and western Georgia"Tallahatta" is an essential formation of the Claiborne Group.The age and correlation of all of the lithostratigraphic units are discussed.
In addition, the Pen Branch fault is recognized in the vicinity of Hancock Landing in eastern Burke County.i TABLE OF CONTENlW INTRODUCTION
............................................................
1 PurposeandSeope
.....................................................
1 LocationofStudyArea
..................................................
1 ...................................................
Physiographicsetting 1 PreviousWork
.......................................................
1 Methods .............................................................
3 Acknowledgements
.....................................................
3 .................................................
GEOLOGY AND HYDROLOGY 5 GeologicSetting
.......................................................
5 ...................................................
HydrogeologicSetting 6 Struch.lralFeature~s
....................................................
10 STRATIGRAPHY
...........................................................
12 OconeeGroup
........................................................
12 SteelCreekFormation
............................................
14 ................................................
SnappFormation 17 UndifferentiatedBLackMingoFormation
...............................
23 ClaiborneGroup
......................................................
31 CongareeFormation
..............................................
33 StillBranchSand
...............................................
43 ...............................
Bennock Millpond Sand Member 48 LisbonFormation
...............................................
63 .........................................
Blue Bluff Member 56 ..................................
McBean Limestone Member 62 .......................................................
BarnwellGroup 64 .............................................
ClincMeldFomation 66 ....................................
Utley Limestone Member 66 ............................................
DryBranchFormation 68 .....................................
Twiggs Clay Lithofacies 70 ....................................
Griflins Landing Member 70 ......................................
Irwinton Sand Member 71 ..............................................
TobaccoRoadSand 72 REFERENCESCITED
.......................................................
73 FIGURES .........................................
Index map of eastern Burke County 2 Index map of core samples within the Trans-River Flow Project area ................
4 Tritium Project stratigraphic and hydrostratigraphic units .........................
7 Correlation chart for the Tritium Project study area and adjacent regions ..............
8 North-south cross-section between TR92-4 and TR92-3 ...........................
9 Map showing location of Dunbarton basin and Pen Branch and Martin faults on SRS .... 11 ....................
Structure contour map of the top of the Steel Creek Formation 18 ............................................
Snapp Formation isopach map 21 Structure contour map of the top of the Snapp Formation
........................
22 Undifferentiated Black Mingo Formation isopach map ...........................
27 TABLE OF CONrENTS IN"TRODUCTION............................................................1 Purpose and Scope 1 Location of Study Area 1 Physiographic Setting 1 Previous Work 1 Methods 3 Acknowledgements 3 GEOLOGY AND HYDROLOGY 5 Geologic Setting 5 Hydrogeologic Setting 6 Structural Features..................................................
..10 STRATIGRAPHY 12 Oconee Group........................................................
12 Steel Creek Formation............................................
14 Snapp Formation................................................
17 Undift'erentiated Black Mingo Formation 23 Claiborne Group 31 Congaree Formation..............................................
33 Still Branch Sand 43 Bennock Millpond Sand Member...............................
48 Lisbon Formation 53 Blue Bluff Member.........................................
56 McBean Limestone Member 62 Barnwell Group.......................................................
64 Clinchfield Formation.............................................
66 Utley Limestone Member 66 Dry Branch Formation............................................
68 Twiggs Clay Lithofacies 70 Griffins Landing Member....................................
70 Irwinton Sand Member......................................
71 Tobacco Road Sand 72 REFERENCES CITED 73 FIGURES 1.Index map of eastern Burke County 2 2.Index map of core samples within the Trans-River Flow Project area 4 3.Tritium Project stratigraphic and hydrostratigraphic units.........................7 4.Correlation chart for the Tritium Project study area and a<ljacent regions 8 5.North-south cross-section between TR92-4 and TR92-3 9 6.Map showing location of Dunbarton basin and Pen Branch and Martin faults on SRS....11 7.Structure contour map of the top of the Steel Creek Formation 18 8.Snapp Formation isopach map............................................
21 9.Structure contour map of the top of the Snapp Formation........................
22 10.Undifferentiated Black Mingo Formation isopach map 27 ii Structure contour map of the top of the Undifferentiated Black Mingo Formation
....... 28 .....................
Undifferentiated BWs Mingo/Snapp Formations ieopach map 29 CongarseFomtioniaopaCnmap
..........................................
39 ......................
Structure contour map of the top of the Congaree Formation 40 ............................................
StiLlBranchSandiaopachmap 46 Structure contour map of the top of the Still Branch Sand
........................
47 ............................................
Lisbon c or mat ion
'bopach map 67 ........................
Structure contour map of the top of the Lisbon Formation 68 ...............................
Geologic map shaKing extent of Barnwell Group 66 TABLES Coredatafmmstudyarea
................................................
6 ..........................................
Core data fmm outside study area 6 ..................
Steel Creek Formation reference sections in eastern Burke County 16 Thicknessvariationsfor Steel CreekFormation
................................
17 ................... Snapp Formation reference sections in the Savannah River area 19 .....................
Undifferentiated Black Mingo Formation reference sections in 26 ...................
Congaree Formation reference sections in eastern Burke County 36 Congaree Formation reference sections in Georgia west of Burke County .............
36 ........................................ Still Branch Sand reference sections 46 .............................
Bennock Millpond Sand Member reference sections 49 ......................................
Blue Bluff Member reference sections 60 ...........................
Thickness variations for McBean Limestone Member 64 APPENDICES Descriptions of core site locations
..........................................
79 Historical review of Black Mingo and Ellenton Formations
........................
83 .....................................
Historical review of Congaree Formation 90 ...................................
Historical review of the McBean Formation 91 PLATES Correlation chart of eastern Burke County stratigraphic unite with adjacent regions of the southern Atlantic and eastern Gulf Coastal Plains ..........
Jacket 11.Structure contour map of the top of the Undi1ferentiated.
Black Mingo Formation 28 12.Undi1ferentiated.
Black Mingo/Snapp Formations isopach map 29 13.Congaree Formation isopach map..........................................
39 14.Structure contour map of the top of the Congaree Formation......................
40 15.Still Branch Sand isopach map............................................
46 16.Structure contour map of the top of the Still Branch Sand........................
47 17.Lisbon Formation isopach map............................................
57 18.Structure contour map of the top of the Lisbon Formation........................
68 19.Geologic map showing extent of Barnwell Group...............................
65 TABLES 1.Core data from study area................................................5 2.Core data from outside study area 6 3.Steel Creek Formation reference sections in eastern Burke................
..15 4.Thickness variations for Steel Creek Formation................................
17 5.Snapp Formation reference sections in the Savannah River area 19 6.Undi1ferentiated Black Mingo Formation reference sections in 25 7.Congaree Formation reference sections in eastern Burke 35 8.Congaree Formation reference sections in Georgia west of Burke 36 9.Still Branch Sand reference sections........................................
45 10.Bennock Millpond Sand Member reference sections 49 11.Blue Bluff Member reference sections....................................
..60 12.Thickness variations for McBean Limestone Member.........................
..64 APPENDICES 1.Descriptions of core site locations..........................................
79 2.Historical review of Black Mingo and Ellenton Formations........................
83 3.Historical review of Congaree Formation.....................................
90 4.Historical review of the McBean Formation...................................
91 PLATES 1.Correlation chart of eastern Burke stratigraphic units with adjacent regions of the southern Atlantic and eastern Gulf Coastal Plains..........
Jacket iii INTRODUCTION Plain sedimentary units outside the Burke County study area. The Georgia Geologic Survey (GGS) Tritium Project was initiated to investigate the nature and distribution of tritium in aquifers in eastern Burke County, Georgia (Summerour, et al, 1994). This investigation began following discovery of measurable tritium in a public water supply well (DeLaigle Mobile Home Park, Figure 1) in January and July, 1991. Core drilling for the project began at the TR92-1 site (Figure 2) in December, 1991. In March, 1992, the U. S. Department of Energy (DOE) provided the Environmental Protection Division (EPD) of the Georgia Department of Natural Resources with $800,000 to conduct the project. In July, 1991, DOE entered into an agreement with the United States Geological Survey (USGS) for an investigation of the conditions under which ground water from the Savannah River Site (SRS) in South Carolina could migrate beneath the Savannah River into Georgia aquifers. This study, originally referred to as the Underflow Project, is now knm as the Trans-River Flow Project (Clarke, et al, 1994). Both the Tritium and the Trans-River Flow projects were initiated due to environmental concerns arising from radioactive releases from the Savannah River Site (SRS) nuclear weapons and research facility, operated by DOE, in South Carolina.
Purpose and Scope The nature of local ground-water conditions is important to both the GGS Tritium and USGS Trans-River Flow Projects.
In order to properly evaluate these conditions, an understanding of the geology and stratigraphy is needed. The objective of this report is to lay a lithostratigraphic foundation, baaed on the North American Stratigraphic Code (19861, upon which further geologic studies and stratigraphic refinements may be made. Lithologic descriptions of core sample8 and outcrops in areas to the east (South Carolina) and to the west (central and west Georgia) were included to provide information concerning the lateral extent of described units and correlation w-kh Coastal Location of Study Area Burke County is located along the Georgia-South Carolina border (Figure 1). The northern boundary of the county (McBeah Creek) is approximately 15 miles southeast of Augusta, Georgia and the southeastern boundary of the county is approximately 70 miles northwest of Savannah, Georgia. The Savannah River Site (SRS) is located directly across the Savannah River from Burke County. The Tritium Project study area is located in the eastern third of Burke County from the Savannah River on the east to Brier Creek on the west and from the Richmond-Burke County line (McBean Creek) on the north to the Burke- Screven County line on the south (Figure 1). The study area is 12 to 19 miles south of the Fall Line, which separates the Coastal Plain and Piedmont physiographic provinces.
Physiographic Setting The Tritium Project study area is within the Louisville Plateau of Cooke (19251, characterized by broad, very gently rolling uplands that contain deeply incised streams. The Louisville Plateau is moderately dissected, with 100 to 160 feet of topographic relief. McBean Creek ddnes the northern boundary of the Louisville Plateau as well as fodng the Richmond/Burke County line in the study area (Figure 1).
The Fall Line hills district lies directly across McBean Creek to the north. The Screven/Burke county line approximates the southern boundary of the Louisville Plateau in the study area, to the south of which is the Vidalia Upland district (Clark and Zisa, 1976). Previous Work Prior to the present investigations, detailed subsur&ce geology (both litho- stratigraphy and hydrogeology) of eastern Burke County was poorly understood.
Exploratory drilling results in northern Burke County were described by LeGrand and Furcron (1966). INTRODUCTION The Georgia Geologic Survey (GGS)Tritium Project was initiated to investigate the nature and distribution of tritium in aquifers in eastern Burke County, Georgia (Summerour, et al, 1994).This investigation began following discovery of measurable tritium in a public water supply well (DeLaigle Mobile Home Park, Figure 1)in January and July, 1991.Core drilling for the project began at the TR92-1 site (Figure 2)in December, 1991.In March, 1992, the U.S.Department of Energy (DOE)provided the Environmental Protection Division (EPD)of the Georgia Department of Natural Resources with$800,000 to conduct the project.In July, 1991, DOE entered into an agreement with the United States Geological Survey (USGS)for an investigation of the conditions under which ground water from the Savannah River Site (SRB)in South Carolina could migrate beneath the Savannah River into Georgia aquifers.This study, originally referred to as the Underflow Project, is now known as the Trans-River Flow Project (Clarke, et al, 1994).Both the Tritium and the Trans-River Flow projects were initiated due to environmental concerns arising from radioactive releases from the Savannah River Site (SRB)nuclear weapons and research facility, operated by DOE, in South Carolina.Purpose and Scope The nature of local ground-water conditions is important to both the GGS Tritium and USGS Trans-River Flow Projects.In order to properly evaluate these conditions, an understanding of the geology and stratigraphy is needed.The objective of this report is to lay a lithostratigraphic foundation, based on the North American Stratigraphic Code (1986), upon which further geologic studies and stratigraphic refinements may be made.Lithologic descriptions of core samples and outcrops in areas to the east (South Carolina)and to the west (central and west Georgia)were included to provide information concerning the lateral extent of described units and correlation wi"'..h Coastal 1 Plain sedimentary units outside the Burke County study area.Location of Study Area Burke County is located along the Georgia-South Carolina border (Figure 1).The northern boundary of the county (McBean Creek)is approximately 15 miles southeast of Augusta, Georgia and the southeastern boundary of the county is approximately 70 miles northwest of Savannah, Georgia.The Savannah River Site (SRB)is located directly across the Savannah River from Burke County.The Tritium Project study area is located in the eastern third of Burke County from thE: Savannah River on the east to Brier Creek on the west and from the Richmond-Burke County line (McBean Creek)on the north to theScreven County line on the south (Figure 1).The study area is 12 to 19 miles south of the Fall Line, which separates the Coastal Plain and Piedmont physiographic provinces.
Physiographic Setting The Tritium Project study area is within the Louisville Plateau of Cooke (1925), characterized by broad, very gently rolling uplands that contain deeply incised streams.The Louisville Plateau is moderately dissected, with 100 to 150 feet of topographic relief.McBean Creek defines the northern boundary of the Louisville Plateau as well as forming the RichmondjBurke County line in the$ldy area (Figure 1).The Fall Line hills district lies directly across McBean Creek to the north.The ScrevenjBurke county line approximates the southern boundary of the Louisville Plateau in the study area, to the south of which is the Vidalia Upland district (Clark and Zisa, 1976).Previous Work Prior to the present investigations, detailed subsurface geology (bothstratigraphy and hydrogeology) of eastern Burke County was poorly understood.
Exploratory drilling results in northern Burke County were described by LeGrand and Furcron (1956).
Savannah River Site miles 1 Figure 1. Index map of eastern Burke County, Georgia. Modified from Summerour and others (1994). Savannah River Site...............
.""."....".....5 miles o 5 Figure 1.Index map of eastern Burke County, Georgia.Modified from Summerour and others (1994).
Subsw4hce studiw of Burke County and acljacent areas were conducted by Herrick (1961) and Herrick and Vorhia (1983). ReconnAinnnnce mapping was conducted by John Sandy for a study of mineral reso- in the Central Sad River area Wurst, et 4 1966). Huddlestun and Hetrick (1979, 1986) provided a delinition of the Barnwell Group in Burke County, as well as areaa to the west and southwest.
Huddlestun (1988) dedned the Altamaha Formation in Burke County. Structural studies in Burke County were conducted by Faye and Prowell (1982) and Bechtel Corporation (1982). Aquifer studies included Upper Three Runs (Vincent, 1982); Gordon (Brooks, et 4 1985; Gorday, 1985); and Dublin and Midville (Clarke, et al, 1985). Prowell and others (1985) produced a cross- section of the upper Coastal Plain in eastern Georgia and western South Carolina.
Outside the study area, extensive subsurface studies were conducted at SRS and the western South Carolina Coastal Plain to the east (Siple, 1967; Nystrom and Willoughby, 1982) and the Georgia Coastal Plain to the west and northwest (Huddlestun, 1988; Huddlestun and Hetrick, 1986, 1991).
Fallaw and Price (1995) named a number of new formations at SRS, some of which are adopted in this report, and presented a very thorough listing of previous work in the area. Methods During this study, approximately 9244 feet of core were examined and described.
The core samples studied (Figure 2, Table 1) were collected from the six GGS Tritium Project sites (TR92-1 through TR92-61, two USGS sites (Millers Pond and Girard), and one core drilled by Georgia Power Company at Plant Vogtle (B-246). Eight cores were drilled in 1982 by Bechtel Corporation (VG-1 through VG-8) in southeastern Burke County along River Road, as well as several across the Savannah River in South Carolina, two of which were used in this study WSC-3 and VSC-4). Other cores from SRS in South Carolina were Psrnmined in the interest of correlation and comparison.
Within the text of this report, the field name of each well, e.g., TRB2-1 (Tritium hject), USGS Millers Pond (TrnneRiver Flow Prqject), VG-1 (Bechtel Corp., for Georgia Power), etc. is used. Core samples from other Georgia Coastal Plain sites are included in Table 2. Lithologic deacriptiona from these cores are included for the purpose of deecrib'hg the lateral extent and cordation with other units. Appendix 1 givw a physical description of the drill site locations as well as other dwignations for these core samples, including GGS numbers. The cores used in this report are stored in the following locations:
GGS cores (McBean, Tritium Project) and USGS Millers Pond core are stored at the GGS warehouse in Atlanta, Ga.; the Bechtel cores (VG1 through VG8 and VSC-3 and VSC- 4) are stored at Georgia Power Plant Vogtle, east of Waynesboro, the USGS Albany core is stored at the USGS warehouse in Reston, Virginia, and the USGS Girard core is stored at the South Carolina Geological Survey warehouse in Columbia, South Carolina.
Core B-246 was inadvertently destroyed while in storage on Plant Vogtle property in the late 1970's. Cores P-18, P 21TA, and P 22TA (Table 1) are in storage in a warehouse at SRS. Initially, the core samples were recovered in order to determine well screen intervals for the Tritium Project and Trans- River Flow Project monitoring wells.
Subsequently, the cores were analyzed to evaluate the subsurface lithostratigraphic and hydrostratigraphic framework of the local aquifers (Figure 3). In addition to lithostratigraphic analysis, micropaleontological identifications were conducted by the senior author, Lucy Edwards and Norm Frederiksen (both of the USGS) for chronostratigraphic and correlation purposes.
Acknowledgements We wish to extend our appreciation to property owners of the drill sites in Burke and Screven Counties for their cooperation and assistance.
We also gratefully acknowledge Lucy Edwards and Norm Fredericksen of the USGS for their time and efforts. Outaide reviews were conducted by John Clarke (USGS), Tom Temples (DOE), and Lucy Edwards CUSGS). Subsurface studies of Burke Count;y and adjacent areas were conducted by Herrick (1961)and Herrick and Vorhis (1963).Reconnaissance mapping was conducted by John Sandy for a study of mineral resources in the Central Savannah River area (Hurst, et al, 1966).Huddlestun and Hetrick (1979, 1986)provided a definition of the Barnwell Group in Burke Count;y, as well as areas to the west and southwest.
Huddlestun (1988)defined the Altamaha Formation in Burke Count;y.Structural studies in Burke Count;y were conducted by Faye and Prowell (1982)and Bechtel Corporation (1982).Aquifer studies included Upper Three Runs (Vincent, 1982);Gordon (Brooks, et al, 1985;Gorday, 1985);and Dublin and Midville (Clarke, et al, 1985).Prowell and others (1985)produced asection of the upper Coastal Plain in eastern Georgia and western South Carolina.Outside the study area, extensive subsurface studies were conducted at SRS and the western South Carolina Coastal Plain to the east (Siple, 1967;Nystrom and Willoughby, 1982)and the Georgia Coastal Plain to the west and northwest (Huddleston, 1988;Huddlestun and Hetrick, 1986, 1991).Fallaw and Price (1995)named a number of new formations at SRS, some of which are adopted in this report, and presented a very thorough listing of previous work in the area.Methods During this study, approximately 9244 feet of core were examined and described.
The core samples studied (Figure 2, Table 1)were collected from the six GGS Tritium Project sites (TR92-1 through TR92-6), two USGS sites (Millers Pond and Girard), and one core drilled by Georgia Power Company at Plant Vogtle246).Eight cores were drilled in 1982 by Bechtel Corporation (VG-1 through VG-8)in southeastern Burke Count;y along River Road, as well as several across the Savannah River in South Carolina, two of which were used in this study (VSC-3 and VSC-4).Other cores from SRS in South Carolina were examined in the interest of correlation and comparison.
Within the text of this report, the field name of each 3 well, e.g., TR92-1 (Tritium Project), USGS Millers Pond (Trans-River Flow Project), VG-1 (Bechtel Corp., for Georgia Power), etc.is used.Core samples from other Georgia Coastal Plain sites are included in Table 2.Lithologic descriptions from these cores are included for the purpose of describing the lateral extent and correlation with other units.Appendix 1 gives a physical description of the drill site locations as well as otherdesignationsfor these core samples, including GGS numbers.The cores used in this report are stored in the following locations:
GGS cores (McBean, Tritium Project)and USGS Millers Pond core are stored at the GGS warehouse in Atlanta, Ga.;the Bechtel cores (VG-1 through VG-8 and VSC-3 and4)are stored at Georgia Power Plant Vogtle, east of Waynesboro, the USGS Albany core is stored at the USGS warehouse in Reston, Virginia, and the USGS Girard core is stored at the South Carolina Geological Survey warehouse in Columbia, South Carolina.Core B-246 was inadvertently destroyed while in storage on Plant Vogtle property in the late 1970's.Cores P-18, P 21TA, and P 22TA (Table 1)are in storage in a warehouse at SRS.Initially, the core samples were recovered in order to determine well screen intervals for the Tritium Project andRiver Flow Project monitoring wells.Subsequently, the cores were analyzed to evaluate the subsurface lithostratigraphic and hydrostratigraphic framework of the local aquifers (Figure 3).In addition to lithostratigraphic analysis, micropaleontological identifications were conducted by the senior author, Lucy Edwards and Norm Frederiksen (both of the USGS)for chronostratigraphic and correlation purposes.Acknowledgements We wish to extend our appreciation to property owners of the drill sites in Burke and Screven Counties for their cooperation and assistance.
We also gratefully acknowledge Lucy Edwards and Norm Fredericksen of the USGS for their time and efforts.Outside reviews were conducted by John Clarke (USGS), Tom Temples (DOE), and Lucy Edwards (USGS).
Figure 2. Index map of core sites within the Trans-River Flow Project area (used in this report). Additional information is within the text, Table 1, and Appendix
- 1. Modified from Summerour and others (1994). Savannah River Site VSC-4*Figure 2.Index map of core sites within the Trans-River Flow Project area (used in this report).Additional information is within the text, Table 1, and Appendix 1.Modified from Summerour and others (1994).N Table 1 Core data from studv area. Cora Sk USGS gr# OGSm lkrthhtllud.
mkngm Surface ElevaUon-feat number number (-1 (-1 ~~OV~M..~~~~ISVOI Tm2-1 3121038 3784 33' w 37 81' 49' 1Q 235 Millen 302016 3758 33' 13' 48' 81' 52' 44' 245 Pond Girard 32Ym n/a 33' 03' 54' 81' 43' 18 250 I I VSG3 n/a n/a 33'07'28' 81' 35' 42' 177 V-SC-4 n/a n/a 33' 06' s 81' 34' 05' 1 65 8246 n/a n/a 33' 08' s 81' 46' 22' 220 P 21TA n/a n/a 33' 08' 48' 81' 36' 27' 207 P 22TA n/a n/a 33' 11' 28' 81' 30' 48' 21 5 P-18 n/a n/a 33' 15' 11' 81' 40' 21' 354 "n/aM-not available or not applicable This project was supported, in part, GEOLOGYANDHYDROLOGY through Cooperative Agreements with the United States Department of the Interior (U. S. Geologic Setting Geological Survey) (Cooperative Agreement Number 1434-92-A-0959) and the U. S. Subsurface stratigraphy of the Tritium Department of Energy (Cooperative Agreement Project study area consists of a southeast Number DE-FG-09-92SR12868).
dipping package of Upper Cretaceous, Paleogene, and Neogene siliciclastic and carbonate rocks (Figures 3, 4, and 5 and Plate 1). Regional dip Table 1 Core data from study area.Core Site USGS grid GGS core North IaUIucIe we.t Iongllude Surfllce Elevation-feetnumbernumber (est.)(est.)Dove Mean Sea 1A¥eI TR92-1 31Z038 3764 33°09'3r 81°49'19" 235 TR92*2 31Z047 3762 33 0 09'U 81°47'23" 285 TR92-3 31Y017 3781 33°06'35" 81°48'54" 195 TR92-4 31ZD50 3782 33°11'30" 81°48'34" 192 TR92-5 31Z089 3792 33°06'or 81°4T 03" 235 TR92-6 31Z1OS 3794 33°10'42" 81°47'10" 240 McBean 3OZD18 3757 33°13'38" 81°55'fJl1'297 Millers 3OZD16 3758 33°13'48" 81°52'44" 245 Pond Girard 32Y02O nja 33°03'54" 81°43'13" 250 VG-1 32Y027 nja 33°04'45" 81°38'39" 155 VG-2 32Y017 nja 33°OS'OS" 81°40'31" 253 VG-3 32Y016 nja 33°04'54" 81°39'32" 165 VG-4 32Y018 nja 33°04'28" 81°41'38" 150 VG-5 33YOO8 nja 33°04'06" 81°37'U 94 VG-6 33YOO7 nja 33°03'11" 81°36'4r 217 VG-7 32Y028 nja 33°OS'54" 81°42'30" 250 VG-8 33Y011 nja 33°02'06" 81°35'00-102 VSC-3 nja nja 33°07'28" 81°35'42" 177 VSC-4 nja nja 33°06'29" 81°34'OS" 165 8-246 nja nja 33oOS'53" 81°46'22" 220 P21TA nja nja 33°OS'48" 81°36'27" 207 P 22TA nja nja 33°11'28" 81°30'48" 215 P-18 nja nja 33°15'11" 81°40'21" 354"nja"-not aV81lable or not applicable This project was supported, in part, through Cooperative Agreements with the United States Department of the Interior (U.S.Geological Survey)(Cooperative Agreement Number 1434-92-A-0959) and the U.S.Department of Energy (Cooperative Agreement Number DE-FG-09-92SR12868).
5 GEOLOGY AND HYDROLOGY Geologic Setting Subsurface stratigraphy of the Tritium Project study area consists of a southeast dipping package of Upper Cretaceous, Paleogene, and Neogene siliciclastic and carbonate rocks (Figures 3, 4, and 5 and Plate 1).Regional dip Core data from outslde study area. -fad above M8an GGS Houston I a 1 ZBZI 1 32030.~ I d37'42 9 I GGS Lauren8 1 GGS Colqultt I I I I I ?/aM-not available or not applicable on the top of the Claiborne Group (typical for the area) is approximately ten feet per mile to n/a n/a the southeast.
The fluvial, coastal marine, and shallow inner neritic marine deposits which compose the subsurface of the study area lie within a transitional "zone" between the Atlantic and Gulf Coastal Plain provinces.
Within this zone, abrupt lateral variations in lithofacies characteristics are common. The Cape Fear Formation, Steel Creek Formation, undifferentiated Black Mingo Formation, and Snapp Formation, McBean Member of the Lisbon Formation and the IMinton and Gfina Landing Members of the Dry Branch Formation and Tobacco Road Sand of the Barnwell Group are southern Atlantic Coastal Plain stratigraphic units (Figure 4 and Plate 1). The Still Branch Formation and Bennock Millpond Sand Member, undifferentiated Lisbon Formation, Blue Bluff Member of the Lisbon Formation, and Twiggs Clay lithofacies of the Barnwell Group are eastern Gulf Coastal Plain stratigraphic units.
The Pio Nono Formation, Gaillard Formation, and Congaree Formation occur both in the Gulf Coastal Plain and the southern ~tlhic Coastal Plain (Figure 4 and Plate 1). Hydrogeologic Setting 3523 3545 The Upper Coastal Plain sediments of the study area are included in the Southeastern Coastal Plain hydrogeologic province (Aadland, et al, 1992). The aquifers of interest in the Trans-River Flow study area are (in descending order): 1.) Upper Three Runs (unconfined) (Aadland, et al, 1992; Summerour, et al, 1994); 2.) Gordon (con6ned) (Brooks, et al, 1985); 3.) Millers Pond (confined) (Falls and Baum, 1995); 4.) Dublin (confined) (Clarke, et al, 1985); and 5.) Midville (confined) (Clarke, et al, 1985). The hydrostratigraphic units discussed in this report include the Upper Three Runs, Gordon, and Millers Pond aquifers.
Downdip, the siliciclastic and carbonate sediments of the Upper Three Runs aquifer become part of the predominantly carbonate Upper Floridan aquifer system (Clarke, et al, 1994) and the siliciclastic sediments of the Gordon aquifer become part of the predominantly carbonate Lower Floridan aquifer (Clarke, et al, 1994). The siliciclastic sediments of the Millers Pond aquifer grade downdip into the clays of the Meyers Branch conhing system (Falls, personal communication, 1995) (Figure 3). 32O30'5W 31' 17' 53' 63O M' 43' 63O 53' 55' 285 350 Table 2 Core data from outside study area.Core Site USGS GGS North IetItucIe (eat.)WMt longitude Surface ElevatIon grid core (eat.)*feet above Meannumbernumber Sea Level GGS Pulaski 3 n/a 3111 32°15'51" 83°28'4T 300 USGS Albany nfa 3187 31°OS'36" 84°06'50" 195 GGS Sumter nfa 3366 32°04'03" 83°59'23" 270 9A GGS Pulaski 5 nfa 3511 32°22'SO" 83°29'1T 355 GGS Laurens 1 nfa 3523 32°30'59" 83°02'43" 285 GGS Colquitt nfa 3545 31°17'53" 83°53'55" 350 11 GGS Houston nfa 3629 32 0 39'2Jj83°37'42" 310 9"n/a"-not available or not applicable on the top of the Claiborne Group (typical for the area)is approximately ten feet per mile to the southeast.
The fluvial, coastal marine, and shallow inner neritic marine deposits which compose the subsurface of the study area lie within a transitional"zone" between the Atlantic and Gulf Coastal Plain provinces.
Within this zone, abrupt lateral variations in lithofacies characteristics are common.The Cape Fear Formation, Steel Creek Formation, undifferentiated Black.Mingo Formation, and Snapp Formation, McBean Member of the Lisbon Formation and the Irwinton and Griffins Landing Members of the Dry Branch Formation and Tobacco Road Sand of the Barnwell Group are southern Atlantic Coastal Plain stratigraphic units (Figure 4 and Plate 1).The Still Branch Formation and Bennock.Millpond Sand Member, undifferentiated Lisbon Formation, Blue Bluff Member of the Lisbon Formation, and Twiggs Clay lithofacies of the Barnwell Group are eastern Gulf Coastal Plain stratigraphic units.The Pio Nono Formation, Gaillard Formation, and Congaree Formation occur both in the Gulf Coastal Plain and the southern Atlantic Coastal Plain (Figure 4 and Plate 1).6 Hydrogeologic Setting The Upper Coastal Plain sediments of the study area are included in the Southeastern Coastal Plain hydrogeologic province (Aadland, et al, 1992).The aquifers of interest in the Trans-River Flow study area are (in descending order): 1.)Upper Three Runs (unconfined)(Aadland, et al, 1992;Summerour, et al, 1994);2.)Gordon (confined)(Brooks, et al, 1985);3.)Millers Pond (confined)(Falls and Baum, 1995);4.)Dublin (confined)(Clarke, et al, 1985);and 5.)Midville (confined)(Clarke, et al, 1985).The hydrostratigraphic units discussed in this report include the Upper Three Runs, Gordon, and Millers Pond aquifers.Downdip, the siliciclastic and carbonate sediments of the Upper Three Runs aquifer become part of the predominantly carbonate Upper Floridan aquifer system (Clarke, et al, 1994)and the siliciclastic sediments of the Gordon aquifer become part of the predominantly carbonate Lower Floridan aquifer (Clarke, et al, 1994).The siliciclastic sediments of the Millers Pond aquifer grade downdip into the clays of the Meyers Branch confining system (Falls, personal communication, 1995)(Figure 3).
Figure 3. Tritium Project stratigraphic and hydrostratigraphic units for Burke County and SRS area. SRS terminology from Aadland and others (1992), Millers Pond aquifer from Falls and Baum (1995). Modified from Summerour and others (1994). Formation1 Burke Co.
SRS Lithology Member Hydrologic Units Hydrologic Units Floridan Aquifer -LA- P --LT LTATLT 3 OTTTT Lisbon Fm. L Still Branch Sd. Congaree Fm. - - - - - - - - - . ------------ - - - - - - - - - - - - . Snapp Fm. Undiff. Black Mingo Fm. Steel Creek Fm. Gaitlard Fm. Coarse sand
~imestone aay Marl and clay are Marl dotted where sandy.
Aquitard Gordon Aquifer Aquitard Millers Pond aquifer Aquitard Dublin Aquifer Gordon Confining unit Floridan Aquifer system Meyers Branch Confining system Dublin Aquifer Dublin Aquifer Aquitard Dublin Aquifer GaiHard Fm.Steel Creek Fm.Formation/
Burke Co.SAS Member Hydrologic Units Hydrologic Units Tobacco Road Sand Upper Three Runs Aquifer (updip)Irwinton Sand Mbr.Dry Branch Fm.Upper Three Runs Aquifer Griffins Landing Mbr.Dry Branch Fm.Floridan Aquifer system Utley Ls.Mbr.(downdip)Clinchfield Fm.McBean I Blue Bluff Mbr.Mbr.Lisbon Fm.Gordon Aquitard Confining unit Bennock Stil Branch Millpond Sd.Mbr.Sd.Congaree Fm.Gordon Aquifer Floridan Aquifer system Snapp Fm.Aquitard Meyers Branch Confining system Undiff.Black Mingo Fm.Millers Pond aquifer------------
Lithology.::::.::::.::.:.:..::::::::**e********************
- .:::::.:.:::::::.::
- a.:.:***********
- .*******::::.:::::::.....::::::;:::::.:::::
(;:-::.:.:.:.-.::-::::
..:-.::::::.
.....-.
ai III****'.****C*U o W e c*u o*'i Q.**:::.::****::.:.-:-**-7-!it*************
-:-.-;o***.:.:.:.*:::..***.*..:..:...::::::.*.::
.*."******.********
7--: r----*****...*****
- '-="=='=5'=
- :i=r----------+-----------!
=i j Q.():*:******:**
iI--------------If-----------t----------t I..£.L*******************
....:......o
- .::::::.::::.:.:.:.
..............Coarse sandLimestone.......[Zill Medium sandMarl b-=-J Clay Marl and clay are dotted where sandy.Figure 3.Tritium Project stratigraphic and hydrostratigraphic units for Burke County and SRS area.SAS terminology from Aadland and others (1992), Millers Pond aquifer from Falls and Baum (1995).Modified from Summerour and others (1994).7 Lisbon Formation Congaree Formation Huber Formation 03 Cusseta Sand Blufftown Formation Tuscaloosa Formation ape Fear Formation Figure 4. Correlation chart for the study area and adjacent regions. Shaded areas inidicate missing stratigraphic intervals.
Modified from Prowell and others (1985) and Summerour and others (1994). A more detailed chart is shown in Plate
- 1. E Cooper Group South Carolina Congaree Formation Fourmile Fm.Fishburne Fm.W Undiff.Black Eastern Georgia this report Congaree Formation Bennock Millpond Sd.StiD Branch Sd Unnamed Huber Formation Barnwell Group lisbon/McBean Formation Eastern Georgia Prowell&others, 1985 Western Georgia 00*rane ormation Ocala Limestone Lisbon Formation ap ormation Snapp Fm..-Q.t----==c....:...:==.:....--+=:::....:...:;.:....------1:::E
- , e Rhems Formation 13 C!J Clayton Formation Mingo Fm.ffl Congaree Formation Sabinian Midwayan Navarroan Jacksonian Claibornian Provincial Stage Ripley Formation Steel Creek Formation Steel Creek Fm.
European Stage Gl 1iii Priabonian
...J Bartonian Q)c: Q)(J 0:5!WLutetian>-Ypresian w 2!Thanetian Q)(J...J 0 Selandian j!>-Danian w co Maastrichtian Modified Black Creek Group Black Creek Formation p======:;:.;:;
Gaillard Formation Cusseta Sand Bluff town Formation Tayloran Austinian Campanian Coniacian Woodbinan Cenomanian Turonian Eaglefordian III:;,CII
&l1:,;,"'::,"';:::"",:
.....:':...::.....:..:"":.:.:"".,::"":::',"".:::.,.,.".""'
- ,:.""',',',.""::.:
....:.::"".::,:""';::':"":
....."'***:.-.1"Sentonian ()Figure 4.
GGS 3782 TR92-4 lQ2' GGS 3794 TR92-6 252' GGS 3762 TR92-2 285' GGS 3792 GGS 3781 TR92-5 % TR92-3 235' 194' 300' Undiff. Black Minw Fm. .__----- ------- - - - - - - - - - ------- -- ------- -. ------ Steel Creek Fm. - - - - - - - --- ------- ------- -- ------- - -. -- GaiWard Fm. --- --. TD 0 505 TD 1010 Sea level I 1 I Figure 5. North-south stratigraphic cross-section between core holes TR92-4 and TR92-3. Modified from Summerour and others (1994.) ----:--------:.
Steel Creek Fm.Undlff.Black Mlnga Fm.100'200'-100'Sea level GGS 3781 TA92-3 194'300ngo Fm.Congaree Fm.Still 8fanch Sand Unditf.Black M'Utley Mbr., Clinchfield Fm.GGS 3792 TA92-5 235'Griffins Landing Mbr.Blue Bluff Mbr.GGS 3762 TR92-2 285'f.sand un Lisbon Fm.
Irwinton Sand Mbr.So..,.:s.-41-----I----------\--+----""""C!., , GGS 3794 TR92-6 252'Bennock MiNpond Sand Mbr.undlff.*and GGS 3782 TR92-4 192'TO 505 o Gaillard Fm.1 mile TO 1010 B Kaolilitic strata...............
Unconformity
--Urit Ixuldaries TO 507-200'-300'Figure 5.North-south stratigraphic cross-section between core holes TR92-4 and TR92-3.Modified from Summerour and others (1994.)
Structural Featurea The most important basement structural feature in the study area is the buried Triassic extensional Dunbarton graben basin (Marine and Siple, 1974; Snipes, et al, 1992, 1993) (Figure 6). Based on simultaneous gravity and magnetic modeling (Cumbest, et al, 1992), the dimensions of the Dunbarton basin are approximately 30 miles (48 km) long, 5,500 feet (1,700 m) deep, and 8 to 10 miles (12.8 to 16 km) wide (Snipes, et al, 1993). The basement rocks adjacent to the Dunbarton basin consist primarily of Paleozoic greenschist facies metavolcanic rocks and amphibolite facies schists and gneisses (Snipes, et al, 1993). Red bed sediments and conglomerates were deposited within the graben (Siple, 1967; Marine and Siple, 1974; Cumbest, et al, 1992; and Snipes, et al, 1993). In Georgia, core TR92-6, north of the basin (Figure
- 2) terminates in weathered biotite schists, whereas the USGS Girard core (Figure 2) terminates in Triassic red beds of the Dunbarton basin. The southeastern boundary fault (or fault zone) of the Dunbarton basin is believed to be the Martin fault (Figure 6) (Snipes, et al, 1993). The northwestern boundary fault (or fault zone) of the Dunbarton basin appears to be coincident with the known location of the Pen Branch fault (Snipes, et al, 1992, 1993). Based on data provided by 57 wells on SRS (Snipes, et al, 1992, 1993)) the Pen Branch fault is slightly sinuous with an average strike of N 55' E. If the Pen Branch fault extends into Georgia, as projected, it would lie beneath the Savannah River channel near Hancock Landing, north of Georgia Power Plant Vogtle (Snipes, et al, 1993). According to Snipes and others (1993, p. 195): "Stratigraphic relationships and seismic studies indicate that the Pen Branch fault is a subvertical growth fault with down-to-the northwest movement sense. Near the center of SRS, the thickness of the Upper Cretaceous clastic strata is about 670 feet (201 m) on the downthrown side, in contrast to 610 feet (185 m) on the up-thrown side. The throw decreases in successively younger beds from 80 to 100 feet (24 to 30 m) at the base of the Lute Cretaceous Cape Fear Formation to 30 feet (9 m) at the top of the Late Eocene Dry Branch Formation.
These relationships yield estimated slip mnges from 0 to 1.5 m/my. with an avemge of about .4 m/my. over the last 85 my.. The down-to-the northwest movement sense for the Pen Bmnch fault is intriguing in that early Mesozoic deposition of fluvial sequences in the Dunbarton basin indicates that the base surface must have been lower that the erosional surface of the crystalline terrain to the northwest.
However, this paleoerosional surface is presently about 80 to 100 feet (24 to 30 m) below the basin surface at the location of the fault. This relationship has led to speculation that the Pen Bmnch fault is a Dunbarton basin border fault reactivated in a reverse sense due to compressional stresses or that it is an antithetic basin fault." Based on core data, the presence of the fault in Georgia is suggested by structure contour and thickness anomalies along the projected Pen Branch fault in eastern Burke County. The anomalies become more pronounced with depth, suggesting continuing fault movement with time. Movement on the Pen Branch fault does not appear to have occurred since the end of the Middle Eocene because there ire no anomalies associated with the fault for sediments deposited after the Middle Eocene (Snipes, et al, 1992, 1993). There is also a lack of historic seismic activity near the fault and an apparent lack of recognizable earthquake-produced liquefaction structures in any of the Tertiary sediments near the fault. Additional information has been provided by a shallow seismic reflection survey conducted during June, 1995, by University of South Carolina personnel.
This seismic survey was conducted along a line between cluster sites TR92-1 and TR92-5 (Figure 2) and indicated the possible existence of a river or scour channel (of unknown orientation) overlying the Pen Branch fault (zone) (Mike Waddell, University of South Carolina, personal communication, 1995). As indicated by the seismic survey data, the channel has a width of approximately 0.75 miles (1.2 km) and a depth of approximately 750 feet (250 m) below current surface level, and has cut as deep as the Middendorf Formation of Prowell and others (1985) (Waddell, personal communication, Stroctural Features The most important basement structural feature in the study area is the buried Triassic extensional Dunbarton graben basin (Marine and Siple, 1974;Snipes, et al, 1992, 1993)(Figure 6).Based on simultaneous gravity and magnetic modeling (Cumbest, et al, 1992), the dimensions of the Dunbarton basin are approximately 30 miles (48 km)long, 5,500 feet (1,700 m)deep, and 8 to 10 miles (12.8 to 16 kIn)wide (Snipes, et al, 1993).The basement rocks adjacent to the Dunbarton basin consist primarily of Paleozoic greenschist facies metavolcanic rocks and amphibolite facies schists and gneisses (Snipes, et al, 1993).Red bed sediments and conglomerates were deposited within the graben (Siple, 1967;Marine and Siple, 1974;Cumbest, et al, 1992;and Snipes, et al, 1993).In Georgia, core TR92-6, north of the basin (Figure 2)terminates in weathered biotite schists, whereas the USGS Girard core (Figure 2)terminates in Triassic red beds of the Dunbarton basin.The southeastern boundary fault (or fault zone)of the Dunbarton basin is believed to be the Martin fault (Figure 6)(Snipes, et al, 1993).The northwestern boundary fault (or fault zone)of the Dunbarton basin appears to be coincident with the known location of the Pen Branch fault (Snipes, et al, 1992, 1993).Based on data provided by 57 wells on SRS (Snipes, et al, 1992, 1993), the Pen Branch fault is slightly sinuous with an average strike of N 55°E.If the Pen Branch fault extends into Georgia, as projected, it would lie beneath the Savannah River channel near Hancock Landing, north of Georgia Power Plant Vogtle (Snipes, et al, 1993).According to Snipes and others (1993, p.195): "Stratigraphic relationships and seismic studies indicate that the Pen Branch fault is a sub vertical growth fault with down-to-the northwest movement sense.Near the center of SRS, the thickness of the Upper Cretaceous clastic strata is about 670 feet (201 m)on the downthrown side, in contrast to 610 feet (185 m)on the up-thrown side.The throw decreases in successively younger beds from 80 to 100 feet (24 to 30 m)at the base of the Late Cretaceous Cape Fear Formation to 30 feet (9 m)at the top of the 10 Late Eocene Dry Branch Formation.
These relationships yield e8timated slip ranges from 0 to 1.5 m/my.with an average of about.4 m/my.over the last 85 my..The down-to-the northwest movement sense for the Pen Branch fault is intriguing in that early Me8ozoic deposition of fluvial sequences in the Dunbarton basin indicates that the base surface must have been lower that the erosional surface of the crystalline terrain to the northwest.
However, this paleoerosional surface is presently about 80 to 100 feet (24 to 30 m)below the basin surface at the location of the fault.This relationship has led to speculation that the Pen Branch fault is a Dunbarton basin border fault reactivated in a reverse sense due to compressional stresses or that it is an antithetic basin fault." Based on core data, the presence of the fault in Georgia is suggested by structure contour and thickness anomalies along the projected Pen Branch fault in eastern Burke County.The anomalies become more pronounced with depth, suggesting continuing fault movement with time.Movement on the Pen Branch fault does not appear to have occurred since the end of the Middle Eocene because there are no anomalies associated with the fault for sediments deposited after the Middle Eocene (Snipes, et al, 1992, 1993).There is also a lack of historic seismic activity near the fault and an apparent lack of recognizable earthquake-produced liquefaction structures in any of the Tertiary sediments near the fault.Additional information has been provided by a shallow seismic reflection survey conducted during June, 1995, by University of South Carolina personnel.
This seismic survey was conducted along a line between cluster sites TR92-1 and TR92-5 (Figure 2)and indicated the possible existence of a river or scour channel (of unknown orientation) overlying the Pen Branch fault (zone)(Mike Waddell, University of South Carolina, personal communication, 1995).As indicated by the seismic survey data, the channel has a width of approximately 0.75 miles (1.2 km)and a depth of approximately 750 feet (250 m)below current surface level, and has cut as deep as the Middendorf Formation of Prowell and others (1985)(Waddell, personal communication, Savannah River Site 5 miles o 5 Figure 6.Map showing location of Dunbarton basin and Pen Branch and Martin faults on SRS and projected extensions into Georgia.Fault data from Snipes, et ai, 1993.
1995). A re-examination of the shallow 8eismic survey of the Savannah River channel (Henry, 1994) shows the possible existence of a buried channel feature near Hancock Landing (John Clarke, USGS, personal communication, 1995; Waddell, - personal communication, 1995). Structure contour and isopach anomalies shown in this report (based on core data), north of Plant Vogtle, may be due to the influence of both the Pen Branch fault zone and the buried channel feature.
Detailed results of this survey will be provided in the Tritium Project Phase II report (Summerour, et al, in prepdon).
STRATIGRAPHY Oconee Group Definition The Oconee Group was introduced informally by Huddlestun (1981) and Schroder (1982), and was formally proposed as a new group by Huddlestun and Hetrick (1991). The Oconee Group includes all pre-Upper Eocene, or pre-Barnwell Group kaolin and kaolinitic sand deposits of fluvial origin in the Fall Line Hills districts of the Coastal Plain of Georgia, South Carolina, and North Carolina (Cooke, 1925; Fenneman, 1938; Cooke, 1936; Clark and Zisa (19761, excluding the Cape Fear Formation.
The named formations that constitute the Oconee Group in Burke County include from oldest to youngest: Pio Nono Formation, Gaillard Formation, Steel Creek Formation, and Snapp Formation of Price and others (1992). The first three formations above are Late Cretaceous in age whereas we consider the Snapp to be Late Paleocene, Selandian, late Midwayan age (Figure 4). Prior to this report, only the Gaillard Formation had been recognized in the study area (Gorday, 1985).
The Black Creek Formation (downdip equivalent of the Gaillard Formation) and the Cape Fear Formation (basal Coastal Plain unit in the area) are not considered to be part of the Oconee Group. Type Locality The name Oconee was taken from the Oconee River in Georgia, that flows through the heart of the Georgia kaolin mining district.
The type area extends from near the Ocmulgee River, in the west, into Washington County, Georgia, in the east. In outcrop, formations that constitute the Oconee Group in its type area include the Pio Nono Formation, Gaillard Formation, and Huber Formation.
Huddlestun and Hetrick (1991) did not select a type locality for the Oconee Group because all good exposures of the soft sands and kaolins are transient.
Oconee sediments are best exposed in sand pits and kaolin mines (that will be reclaimed) and are rarely well-exposed in roadcuts.
Natural exposures are either too small or too weathered to observe the wide variation in lithologies present within the Oconee Group. Two cores from the Deepstep area of Washington County include parts of the Oconee Group, whereas core GGS Houston 9 (Table 2), though not in the "type arean, contains a more complete Oconee Group section. Lithology Typical Oconee Group deposits consist of a series of fining-upward sequences.
Basal sediments generally consist of crudely cross- bedded, poorly sorted, pebbly to gravelly, kaolinitic sand with variable quantities of kaolin clasts and kaolin cobbles (rarely bauxite or pseudo-bauxite cobbles). These basal sand units are prominently and, in many places, dramatically stratified with horizontal to undulatory bedding, and planar and trough cross bedding on small to large scales. Above the basal beds, sands generally fine upward and become better sorted, more thinly bedded, and more finely micaceous.
The middle and upper parts of the fining-upward sequences generally consist either of heavy mineral-rich, moderately to well-sorted, undulatory to horizontally bedded, fine-to medium-grained sand or of small to large lenses of finely sandy and micaceous to relatively pure kaolin. 1995).A re-examination of the shallow seismic survey of the Savannah River channel (Henry, 1994)shows the possibleexistenceof a buried channel feature near Hancock Landing (John Clarke, USGS, personal communication, 1995;Waddell" personal communication, 1995).Structure contour and isopach anomalies shown in this report (based on core data), north of Plant Vogtle, may be due to the influence of both the Pen Branch fault zone and the buried channel feature.Detailed results of this survey will be provided in the Tritium Project Phase IT report (Summerour, et al, in preparation).
STRATIGRAPHY Oconee Group Definition The Oconee Group was introduced informally by Huddlestun (1981)and Schroder (1982), and was formally proposed as a new group by Huddlestun and Hetrick (1991).The Oconee Group includes all pre-Upper Eocene, or pre-Barnwell Group kaolin and kaolinitic sand deposits of fluvial origin in the Fall Line Hills districts of the Coastal Plain of Georgia, South Carolina, and North Carolina (Cooke, 1925;Fenneman, 1938;Cooke, 1936;Clark and Zisa (1976), excluding the Cape Fear Formation.
The named formations that constitute the Oconee Group in Burke County include from oldest to youngest: Pio Nono Formation, Gaillard Formation, Steel Creek Formation, and Snapp Formation of Price and others (1992).The first three formations above are Late Cretaceous in age whereas we consider the Snapp to be Late Paleocene, Selandian, late Midwayan age (Figure 4).Prior to this report, only the Gaillard Formation had been recognized in the study area (Gorday, 1985).The Black Creek Formation (downdip equivalent of the Gaillard Formation) and the Cape Fear Formation (basal Coastal Plain unit in the area)are not considered to be part of the Oconee Group.12 Type Locality The name Oconee was taken from the Oconee River in Georgia, that flows through the heart of the Georgia kaolin mining district.The type area extends from near the Ocmulgee River, in the west, into Washington County, Georgia, in the east.In outcrop, formations that constitute the Oconee Group in its type area include the Pio Nono Formation, Gaillard Formation, and Huber Formation.
Huddlestun and Hetrick (1991)did not select a type locality for the Oconee Group because all good exposures of the soft sands and kaolins are transient.
Oconee sediments are best exposed in sand pits and kaolin mines (that will be reclaimed) and are rarely well-exposed in roadcuts.Natural exposures are either too small or too weathered to observe the wide variation in lithologies present within the Oconee Group.Two cores from the Deepstep area of Washington County include parts of the Oconee Group, whereas core GGS Houston 9 (Table 2), though not in the"type area", contains a more complete Oconee Group section.Lithology Typical Oconee Group deposits consist of a series of fining-upward sequences.
Basal sediments generally consist of crudelybedded, poorly sorted, pebbly to gravelly, kaolinitic sand with variable quantities of kaolin clasts and kaolin cobbles (rarely bauxite or pseudo-bauxite cobbles).These basal sand units are prominently and, in many places, dramatically stratified with horizontal to undulatory bedding, and planar and trough cross bedding on small to large scales.Above the basal beds, sands generally fine upward and become better sorted, more thinly bedded, and more finely micaceous.
The middle and upper parts of the fining-upward sequences generally consist either of heavy mineral-rich, moderately to well-sorted, undulatory to horizontally bedded, fine-to medium-grained sand or of small to large lenses of finely sandy and micaceous to relatively pure kaolin.
The tops of fininp-upward sequences have uneven sdms, indicating some scour and erosion prior to deposition of the overlying fining-upward sequence.
Fining-upward sequences generally cannot be traced across large pits and, therefore, are not laterally continuous.
Channel cut-and-5U structures of variable scale are commonly well-exposed in kaolin pits.
Sands of the Oconee Group are kaolinitic to some degree, micaceous and feldspathic.
Some formations and bede are more feldspathic than others. The sands are laminated to thickly bedded, finely to coarsely micaceous, with common micaceous bedding planes.
Dark minerals are locally abundant and occur both scattered through the sands or as thin dark layers or lenses that appear to be carbonaceous or mangan&rous wad (MnO,). All the formations of the Oconee Group are kaolinitic (rarely smectitic or bauxitic), and contain clasts and cobbles of kaolin, small to large lenses and irregular-shaped masses of kaolin, small to large lenticular massea of micaceous, sandy kaolin to relatively pure kaolin. The lenses of kaolin range in thickness from a few feet (less than 1 m) to approximately 70 feet (21 m), and in extent from several hundred square yards (approximately several hundred square meters) to several hundred acres. Small to large lenses of variably carbonaceous and lignitic sands and cleys commonly are scattered throughout the Oconee Group. The organics occur as finely disseminated carbonaceous material, chiefly as lignitic or carbonaceous flecks of uncertain origin, discrete carbonized fragments of woody material (lignite), and carbonized impressions of vegetation, Generally the carbonaceous lenses grade in all directions into noncarbonaceous sand, kaolinitic sand, or kaolin. Organic content of the lenses range from minor (based on grey coloration of the sediment due to finely disseminated carbonaceous material in the sand and kaolin) to lenses of almost pure carbonaceous kaolin and lignite. In the Gaillard Formation, Middendorf Formation, Steel Creek Formation, Snapp Formation, and Huber Formation, the sand is characterbtically white to light gray in color;. however, the kaolins of the Pio Nono Formation, Steal Creek Formation, and Snapp Formation typically are strongly pigmented (weathered) over most of their surface and subsurface extent This suggests that the high pigmentation of the formations was penemntemporaneous with deposition of the formations. Numerous sand intervals in the Steel Creek Formation have little pigmentation and lithologically resemble the Gaillard Formation. Stratigraphic Relationships The outcrop belt of the Oconee Group extends from eastern Alabama through South Carolina into North Carolina.
Because there are local outliers ofthe group north of the Fall line, the Oconee Group probably extended some distance north of the present Fall Line. The Oconee Group in Burke County is a subsurface unit. It grades downdip or seaward into various Upper Cremus and lower Tertiary formations coastal marine to marine formations in Burke and Screven Countieg Georgia. In Burke County, the Oconee Group disconformably overlies the Cape Fear Formation. The uppermost formation of the Oconee Group in Burke County, the Snapp Formation, is disconformably overlain by the Congaree Formation.
The Congaree appears to pinch out updip in Richmond County immediately north of McBean Creek. Only three cores penetrate the entire Oconee Group in Burke County: the USGS EJIillers Pond core, the GGS Tritium Project core TR92-6, and the USGS Girard core (Figure 2). The total cumulative thickness of the Oconee Group in the USGS Millers Pond core is 525 feet (160 m), in core TR.92-6 the cumulative thicknees is 617 feet (168 m), and in the Girard core the Oconee Group is 522 feet (159 m). There is no apparent thickening of the Oconee Group southeastward through Burke County because the Gaillard Formation grades downdip into 165 feet (47 m) of Black Creek Formation in the southern part of the county and the Pio Nono grades downdip into an unnamed formation in central and southern Burke County that is not Oconee Group. The tops of fining-upward sequences have uneven surfaces, indicating some scour and erosion prior to deposition of the overlying fining-upward sequence.Fining-upward sequences generally cannot be traced across large pits and, therefore, are not laterally continuous.
Channel cut-and-fill structures of variable scale are commonly well-exposed in kaolin pits.Sands of the Oconee Group are kaolinitic to some degree, micaceous and feldspathic.
Some formations and beds are more feldspathic than others.The sands are laminated to thickly bedded, finely to coarsely micaceous, with common micaceous bedding planes.Dark minerals are locally abundant and occur both scattered through the sands or as thin dark layenl or lenses that appear to be carbonaceous or manganiferous wad (Mn0 2).All the formations of the Oconee Group are kaolinitic (rarely smectitic or bauxitic), and contain clasts and cobbles of kaolin, small to large lenses and irregular-shaped masses of kaolin, small to large lenticular masses of micaceous, sandy kaolin to relatively pure kaolin.The lenses of kaolin range in thickness from a few feet aess than 1 m)to approximately 70 feet (21 m), and in extent from several hundred square yards (approximately several hundred square meters)to several hundred acres.Small to large lenses of variably carbonaceous and lignitic sands and commonly are scattered throughout the Oconee Group.The organics occur as finely disseminated carbonaceous material, chiefly as lignitic or carbonaceous flecks of uncertain origin, discrete carbonized fragments of woody material (lignite), and carbonized impressions of vegetation.
Generally the carbonaceous lenses grade in all directions into noncarbonaceous sand, kaolinitic sand, or kaolin.Organic content of the lenses range from minor (based on gray coloration of the sediment due to finely disseminated carbonaceous material in the sand and kaolin)to lenses of almost pure carbonaceous kaolin and lignite.In the Gaillard Formation, Middendorf Formation, Steel Creek.Formation, Snapp Formation, and Huber Formation, the sand is characteristically white to light gray in color;.13 however, the kaolins of the Pio Nono Formation, Steel Creek.Formation, and Snapp Formation t3'Pically are strongly pigmented (weathered) over most of their surface and subsurface extent.This suggests that the high pigmentation of the formations was penecontemporaneous with deposition of the formations.
Numerous sand intervals in the Steel Creek.Formation have little pigmentation and lithologically resemble the Gaillard Formation.
Stratigraphic Relationships The outcrop belt of the Oconee Group extends from eastem Alabama through South Carolina into North Carolina.Because there are local outliers of the group north of the Fall line, the Oconee Group probably exten,ded some distance north of the present Fall Line.The Oconee Group in Burke County is a subsurface unit.It grades downdip or seaward into various Upper Cretaceous and lower Tertiary formations coastal marine to marine formations in Burke and Screven Counties, Georgia.In Burke County, the Oconee Group disconformably overlies the Cape Fear Formation.
The uppermost formation of the Oconee Group in Burke County, the Snapp Formation, is disconformably overlain by the Congaree Formation.
The Congaree appears to pinch out updip in Richmond County immediately north of McBean Creek.Only three cores penetrate the entire Oconee Group in Burke County: the USGS Millenl Pond core, the GGS Tritium Project core TR92-6, and the USGS Girard core (Figure 2).The total cumulative thickness of the Oconee Group in the USGS Millenl Pond core is 525 feet (160 m), in core TR92-6 the cumulative thickness is 517 feet (158 m), and in the Girard core the Oconee Group is 522 feet (159 m).There is no apparent thickening of the Oconee Group southeastward through Burke County because the Gaillard Formation grades downdip into 155 feet (47 m)of Black Creek.Formation in the southem part of the county and the Pio Nono grades downdip into an unnamed formation in central and southem Burke County that is not Oconee Group.
Sedimentary features such as bioturbation and herring-bone cm bedding, and lithic components such as limeatone, calcite, dolostone, dolomite, glauconite, phasphate, and marine fossils characteristic of coastal and near- shore marine deposits are absent in the Oconee Group. Fossils include palynomorphs and plant fossils. Land vertebrate foesile and associated trace fossils such as animal trails have not been reported from Oconee Group deposits. Similarly, shallow water sedimentary structures such as symmetrical ripple marks or mud cracks also have not been reported from the Oconee Group in Georgia. Considering the above observations, the Oconee Group appears to have been deposited in an area of rapidly shifting river channels and currents such as in a continuously-saturated, braided river system. In Burke County, Georgia, the age range of the Oconee Group is Late Cretaceous, probably Austinian (early Santonian) through early Navarroan (early Maashichtian), to Late Paleocene, late Midwayan, Selandian.
In southern Richmond County the upper part of the Oconee Group is Maastrichtian, Danian, and Selandian in age (see Huddlestun and Hetrick, 1991 for more discussion of the age of the Oconee Group). Steel Creek Formation Definition The Steel Creek Formation was named by Fallaw and Price (1992, 1995) for a subsurface, interbedded, varicolored and mottled, kaolin and light-gray sand formation in the Cretaceous part of the Oconee Group in SRS in Barnwell County, South Carolina.
In eastern Burke County, Georgia, the Steel Creek Formation overlies the Gaillard Formation and disconformably underlies the unMerentiated Black Mingo Formation.
Although the Steel Creek is a subsurface formation in Burke County, it may be the uppermost Cretaceous formation that crops out in Richmond County south of Augusta In the past, the Steel Creek Formation was included in the Tuscaloosa Formation of Siple (1967) and Bechtel(1982), undi£ferentiated Oconee Group by Huddlestun (19811, Gaillard Formation by Gorday (1982) and Black Creek Formation
(?) by Faye and Prowell (1982). The lithology ofthe Steel Creek Formation resembles that of the Pio Nono Formation more than any other formation of the Oconee Group. Type Locality The Steel Creek Formation is named for Steel Creek, a small tributary of the Savannah River, approximately 3 miles (0.9 km) northwest of the AUendale/Barnwell Counties line and 1.3 miles (0.4 km) northeast of S.C. Hwy. 125 in southern Barnwell County. The site of the core P 21TA in the Savannah River Site is the type locality of the formation. The coordinates of the site of the core P 21TA is 33' 08' 48" North Latitude and 81' 36' 27" West Longitude.
The core site is on the Girard NE, USGS 1:24,000 topographic quadrangle sheet. The type section, or unit-stratotype (holo-stratotype), of the Steel Creek Formation is in the interval from 453 feet to 594 feet in the core. The Paleocene Sawdust Landing Formation overlies the Steel Creek at 453 feet in the type core and the Black Creek Formation underlies the Steel Creek at 594 feet. Three GGS Tritium Project cores, TR92-2, TR92-4, and TR92-6 (Figure 2) are designated as reference localities for the Steel Creek Formation in Georgia The core aite localities are described in Appendix 1, and the coordinates are listed in Table 1. The core intervals for these reference sections (hypostratotypes) for the Steel Creek Formation are listed in Table 3. The Steel Creek in core TR92-2 is typical for the formation in eastern Burke County and consists of several fining-upward sequences.
In core TR92-4, the Steel Creek consists mostly of highly pigmented kaolins to sandy kaolins with minor light gray sand and is disconformably underlain by the Gaillard Formation.
In core 7392-6, the Steel Creek Formation interval is Lithologically typical of the unit and is conformably or panwonformably Sedimentary features such as bioturbation and herring-bone cross bedding, and lithic components such as limestone, calcite, dolostone, dolomite, glauconite, phosphate, and marine fossils characteristic of coastal andshore marine deposits are absent in the Oconee Group.Fossils include palynomorphs and plant fossils.Land vertebrate fossils and associated trace fossils such as animal trails have not been reported from Oconee Group deposits.Similarly, shallow water sedimentary structures such as symmetrical ripple marks or mud cracks also have not been reported from the Oconee Group in Georgia.Considering the above observations, the Oconee Group appears to have been deposited in an area of rapidly shifting river channels and currents such as in a continuously-saturated, braided river system.Age In Burke County, Georgia, the age range of the Oconee Group is Late Cretaceous, probably Austinian (early Santonian) through early Navarroan (early Maastrichtian), to Late Paleocene, late Midwayan, Selandian.
In southern Richmond County the upper part of the Oconee Group is Maastrichtian, Danian, and Selandian in age (see Huddlestun and Hetrick, 1991 for more discussion of the age of the Oconee Group).Steel Creek Formation Definition The Steel Creek Formation was named by Fallaw and Price (1992, 1995)for a subsurface, interbedded, varicolored and mottled, kaolin and light-gray sand formation in the Cretaceous part of the Oconee Group in SRS in Barnwell County, South Carolina.In eastern Burke County, Georgia, the Steel Creek Formation overlies the Gaillard Formation and disconformably underlies the undifferentiated Black Mingo Formation.
Although the Steel Creek is a subsurface formation in Burke County, it may be the uppermost Cretaceous 14 formation that crops out in Richmond County south of Augusta.In the past, the Steel Creek Formation was included in the Tuscaloosa Formation of Siple (1967)and Bechtel (1982), undifferentiated Oconee Group by Huddlestun (1981), Gaillard Formation by Gorday (1982)and Black Creek Formation (?)by Faye and Prowell (1982).The lithology of the Steel Creek Formation resembles that of the Pio Nono Formation more than any other formation of the Oconee Group.Type Locallty The Steel Creek Formation is named for Steel Creek, a small tributary of the Savannah River, approximately 3 miles (0.9 km)northwest of the Allendale/Barnwell Counties line and 1.3 miles (0.4 km)northeast of S.C.Hwy.125 in southern Barnwell County.The site of the core P 21 TA in the Savannah River Site is the type locality of the formation.
The coordinates of the site of the core P 21TA is 33 0 08'48" North Latitude and 81 0 36'27" West Longitude.
The core site is on the Girard NE, USGS 1:24,000 topographic quadrangle sheet.The type section, or unit-stratotype (holo-stratotype), of the Steel Creek Formation is in the interval from 453 feet to 594 feet in the core.The Paleocene Sawdust Landing Formation overlies the Steel Creek*at 453 feet in the type core and the Black Creek Formation.
underlies the Steel Creek at 594 feet.Three GGS Tritium Project cores, TR92-2, TR92-4, and TR92-6 (Figure 2)are designated as reference localities for the Steel Creek Formation in Georgia.The core site localities are described in Appendix 1, and the coordinates are listed in Table 1.The core intervals for these reference sections (hypostratotypes) for the Steel Creek Formation are listed in Table 3.The Steel Creek in core TR92-2 is typical for the formation in eastern Burke County and consists of several fining-upward sequences.
In core TR92-4, the Steel Creek consists mostly of highly pigmented kaolins to sandy kaolins with minor light gray sand and is disconformably underlain by the Gaillard Formation.
In core TR92-6, the Steel Creek Formation interval is lithologically typical of the unit and is conformably or paraconformably Table 3 Steel Creek Formation reference sections In eastern Burke County. Top of formcltlon-I ~mof Elavolion fonnatlon-Core Sb, 6ee Flgure 2 Table 1 GGS core numbof abow M.M !ih Lwd underlain by the Gaillard Formation.
The Steel Creek is disconformably overlain by the undifferentiated Black Mingo Formation in all three cores. In the USGS Girard core, the Gaillard grades downward into the Black Creek Formation.
285 Lithology surface The Steel Creek Formation commonly is made up of a series of fining upward sequences.
Kaolin and sand are the dominant lithic components of the formation. Kaolin occurs interstitially and, more commonly, as thin to thick beds or lenses. Some beds of sand appear to be almost devoid of kaolin. Scattered kaolin clasts are rare. Minor lithic components include sparse to common, finely to coarsely grained mica. The Steel Creek is more micaceous than overlying formations. Gypsum-and sulphur- bloom occurs in some thin intervals on the cores; carbonaceous intervals and lignitic fragments are rare; pyrite is rare and occurs as dustings along partings or within the kaolins and dark minerals are common. Quartz pebbles are rare, and scattered throughout beds of coarser sand.
The sand ranges from very fine grained and well-sorted (especially in the upper part of fining upward sequences) to coarse, granular, pebbly, and very poorly sorted in the lower part of a fining upward sequences. The quartz sand is variably coherent to incoherent, probably depending on the amount of interstitial kaolin. Sand beds generally are massive-bedded and structureless.
However, crude bedding is commonly seen in some of the intervals of h* below surface 402 coherent sand, and scattered concentrations of dark minerals define some crude bedding planes.
The colors of most sand intervals range from light-gray to white. Where the sands are pigmented, the colors range froni shades of reddish brown, purple, pale orange, brown, and gray- Kaolin beds are generally silty to sandy, variably and finely micaceous, and contain varying amounts of dark minerals.
Some beds appear to contain a trace of interstitial silica. "Hematitic" spherules or "ooids" occur within the kaolin in one core (TR92-4). Sand content within the kaolin beds is variable, some intervals are almost barren of sand whereas other intervals are very sandy.
Sand size within kaolin beds ranges from very fine-grained and well-sorted, to coarse-grained and very poorly sorted. The kaolin beds are commonly massive- bedded and structureless.
The kaolin is dense, tough, brittle and hard, breaking with an irregular, hackly fracture reminiscent of the commercial "hard" kaolins.
Some kaolin is waxy to the touch and slickensided joints are common. Kaolin witl? subconchoidal fracture occurs in some rare and scattered thin intervals. Individual kaolin beds may be as much as 69 feet (21 m) thick. Kaolin in the top several feet of the formation is commonly "bleached" very.light gray to very pale orange and may contain finely disseminated pyrite. Kaolin beds in general are highly and complexly pigmented throughout with extremely irregular mottles, blotches, and almost microscopic root-like streaks. Colors range from white to varying shades of gray 537 (core bottom) Table 3 Steel Creek Formation reference sections In eastern Burke County.Core Site, GGS Site Top of formatlon-Bottom of see figure 2 core Elevation feet below formlltlon-Table 1 number above Mean Sell.u....ce feet below.urf8ce Level TR92-2 GG8-3762 285 402 537 (core bottom)TR92-4 GG8-3782 192 386 501 TR92-6 GG8-3794 240 324 415 underlain by the Gaillard Formation.
The Steel Creek is disconformably overlain by the undifferentiated Black Mingo Formation in all three cores.In the USGS Girard core, the Gaillard grades downward into the Black Creek Formation.
Lithology The Steel Creek Formation commonly is made up of a series of fining upward sequences.
Kaolin and sand are the dominant lithic components of the formation.
Kaolin occurs interstitially and, more commonly, as thin to thick beds or lenses.Some beds of sand appear to be almost devoid of kaolin.Scattered kaolin clasts are rare.Minor lithic components include sparse to common, finely to coarsely grained mica.The Steel Creek is more micaceous than overlying formations.
Gypsum-andbloom occurs in some thin intervals on the cores;carbonaceous intervals and lignitic fragments are rare;pyrite is rare and occurs as dustings along partings or within the kaolins and dark minerals are common.Quartz pebbles are rare, and scattered throughout beds of coarser sand.The sand ranges from very fine grained and well-sorted (especially in the upper part of fining upward sequences) to coarse, granular, pebbly, and very poorly sorted in the lower part of a fining upward sequences.
The quartz sand is variably coherent to incoherent, probably depending on the amount of interstitial kaolin.Sand beds generally are massive-bedded and structureless.
However, crude beddingcommonly seen in some of the intervals of 15 coherent sand, and scattered concentrations of dark minerals define some crude bedding planes.The colors of most sand intervals range from light-gray to white.Where the sands are pigmented, the colors range from shades of reddish brown, purple, pale orange, brown, and gray.Kaolin beds are generally silty to sandy, variably and finely micaceous, and contain varying amounts of dark minerals.Some beds appear to contain a trace of interstitial silica."Hematitic" spherules or"ooids" occur within the kaolin in one core (TR92-4).Sand content within the kaolin beds is variable, some intervals are almost barren of sand whereas other intervals are very sandy.Sand size within kaolin beds ranges from very fine-grained and well-sorted, to coarse-grained and very poorly sorted.The kaolin beds are commonlybedded and structureless.
The kaolin is dense, tough, brittle and hard, breaking with an irregular, hackly fracture reminiscent of the commercial"hard" kaolins.Some kaolin is waxy to the touch and slickensided joints are common.Kaolin with sub conchoidal fracture occurs in some rare and scattered thin intervals.
Individual kaolin beds may be as much as 69 feet (21 m)thick.Kaolin in the top several feet of the formation is commonly"bleached" very.light gray to very pale orange and may contain finely disseminated pyrite.Kaolin beds in general are highly and complexly pigmented throughout with extremely irregular mottles, blotches, and almost microscopic root-like streaks.Colors range from white to varying shades of gray where carbonaceous and pyritic. Other colors include shades of red, pink, reddish brown, purple, orange, yellowish brawn, yellow, gray, and yellowish green.
Stratigraphic Relationships The Steel Creek Formation is known to underlie eastern Burke County and has also been identified in Bechtel Corporation cores from Allendale County, South Carolina.
Neither its known western nor southern limits have been identiiied in Georgia. However, its downdip limit is probably in Screven County.
The Steel Creek Formation is not known to crop out in the kaolin mining district in Georgia. Farther west, the coastal marine Nakomis Formation of Huddlestun and Hetrick (1991) is the most updip lower Navarroan formation that occurs in the Steel Creek stratigraphic position.
Either early Navarroan fluvial deposits were eroded prior to the Paleocene or were not deposited in central and southwestern Georgia. In all sufficiently deep cores in Burke County, the Steel Creek Formation conformably or paraconformably overlies the Gaillard Formation.
The contact relationships between the Gaillard and the Steel Creek are generally ambiguous due to several factors including:
1.) poor core recovery; 2.) the frequent lithologic similarity of uppermost Gaillard and lowermost Steel Creek sands or Gaillard sands underlying lithologically similar Steel Creek sands; or 3.) massive reworking of Gaillard sediments into basal Steel Creek sediments during initial deposition of the Steel Creek. In southernmost Burke County, south of Girard, the Steel Creek Formation probably directly overlies the Black Creek Formation, the downdip equivalent of the Gaillard Formation.
The Steel Creek Formation in Burke County is disconformably overlain by the undifferentiated Black Mingo Formation.
This contact is especially dramatic where carbonaceous clays or fine sands of the Black Mingo lie directly on Steel Creek kaolins.
In those examples, the top few feet of the Steel Creek Formation is "bleached" of pigment and fine-grained pyrite has formed in joints or burrows in the underlying sediment.
Where the basal Black Mingo and uppermost Steel Creek are coarsely sandy, micaceous, and poorly sorted, the contact between the two formations is difficult to discern. In this situation, the Black Mingo/Steel Creek contact appears to be only a minor bed change.
The Steel Creek Formation is distinguished from other formations of the Oconee Group in that; 1.) the kaolin beds are numerous and may constitute more than half of the Steel Creek section in any particular core; 2.) the kaolins (and some sands) are generally highly pigmented and mottled (generally the associated sands are not pigmented or only mildly pigmented);
and 3.), the Steel Creek kaolins are tough, waxy, commonly slickensided and break with a hackly, uneven fracture.
We know of no soft, conchoidally fracturing kaolin beds in the Steel Creek Formation that resemble the soft kaolins of the Gaillard Formation (especially the Buffalo Creek Kaolin Member). Only five cores have penetrated the entire Steel Creek Formation; therefore, the regional or local thickness distribution patterns cannot be clearly defined. However, assuming the upper and lower contacts of the formation have been correctly identified, there appears to be no systematic thickness changes in the formation in the Savannah River area. The thickness of the Steel Creek Formation ranges from 68 feet (21 m) thick in the USGS Millers Pond core, to more than 135 feet (41 m) thick in the Bechtel core VSC-4 near the Savannah River in northern Allendale County, South Carolina (Table 4). There is a relatively consistent southeast dip of the upper surface of the Steel Creek, except where influenced by the projected location of the Pen Branch fault, northwest of Plant Vogtle (Figure 7). The environment of deposition of the Steel Creek Formation was fluvial, and the formation was probably deposited by a system of braided streams draining the adjacent Piedmont Province.
where carbonaceous and pyritic.Other colors include shades of red, pink, reddish brown, purple, orange, yellowish brown, yellow, gray, and yellowish green.Stratigraphic Relationships The Steel Creek Formation is known to underlie eastern Burke County and has also been identified in Bechtel Corporation cores from Allendale County, South Carolina.Neither its known western nor southern limits have been identified in Georgia.However, its downdip limit is probably in Screven County.The Steel Creek Formation is not known to crop out in the kaolin mining district in Georgia.Farther west, the coastal marine Nakomis Formation of Huddlestun and Hetrick (1991)is the most updip lower Navarroan formation that occurs in the Steel Creek stratigraphic position.Either early Navarroan fluvial deposits were eroded prior to the Paleocene or were not deposited in central and southwestern Georgia.In all sufficiently deep cores in Burke County, the Steel Creek Formation conformably or paraconformably overlies the Gaillard Formation.
The contact relationships between the Gaillard and the Steel Creek are generally ambiguous due to several factors including:
1.)poor core recovery;2.)the frequent lithologic similarity of uppermost Gaillard and lowermost Steel Creek sands or Gaillard sands underlying lithologically similar Steel Creek sands;or 3.)massive reworking of Gaillard sediments into basal Steel Creek sediments during initial deposition of the Steel Creek.In southernmost Burke County, south of Girard, the Steel Creek Formation probably directly overlies the Black Creek Formation, the downdip equivalent of the Gaillard Formation.
The Steel Creek Formation in Burke County is disconformably overlain by the undifferentiated Black Mingo Formation.
This contact is especially dramatic where carbonaceous clays or fine sands of the Black Mingo lie directly on Steel Creek kaolins.In those examples, the top few feet of the Steel Creek Formation is"bleached" of pigment and fine-grained pyrite has formed in joints or 16 burrows in the underlying sediment.Where the basal Black Mingo and uppermost Steel Creek are coarsely sandy, micaceous, and poorly sorted, the contact between the two formations is difficult to discern.In this situation, the Black Mingo/Steel Creek contact appears to be only a minor bed change.The Steel Creek Formation is distinguished from other formations of the Oconee Group in that;1.)the kaolin beds are numerous and may constitute more than half of the Steel Creek section in any particular core;2.)the kaolins (and some sands)are generally highly pigmented and mottled (generally the associated sands are not pigmented or only mildly pigmented);
and 3.), the Steel Creek kaolins are tough, waxy, commonly slickensided and break with a hackly, uneven fracture.We know of no soft, conchoidally fracturing kaolin beds in the Steel Creek Formation that resemble the soft kaolins of the Gaillard Formation (especially the Buffalo Creek Kaolin Member).Only five cores have penetrated the entire Steel Creek Formation; therefore, the regional or local thickness distribution patterns cannot be clearly defined.However, assuming the upper and lower contacts of the formation have been correctly identified, there appears to be no systematic thickness changes in the formation in the Savannah River area.The thickness of the Steel Creek Formation ranges from 68 feet (21 m)thick in the USGS Millers Pond core, to more than 135 feet (41 m)thick in the Bechtel core VSC-4 near the Savannah River in northern Allendale County, South Carolina (Table 4).There is a relatively consistent southeast dip of the upper surface of the Steel Creek, except where influenced by the projected location of the Pen Branch fault, northwest of Plant Vogtle (Figure 7).The environment of deposition of the Steel Creek Formation was fluvial, and the formation was probably deposited by a system of braided streams draining the adjacent Piedmont Province.
Table 4 Thickness variations for Steek Creek Formation.
Core Slte USGS Millers Pond The Steel Creek Formation is mostly nonfossiliferous. Samples from the few, thin carbonaceous intervals of the formation in Georgia are barren of pollen so no direct biostratigraphic information is available.
However, in terms of stratigraphic position and physical correlation, the Steel Creek Formation stratigraphically overlies the Campanian (Tayloran)
Gaillard Formation which suggests that the Steel Creek may be early Maastrichtian (early Navarroan) in age. According to Fallaw and Price (1995): 'Wood fiagnents, spores, pollen, and rare dinoflagellates have been found in the SRS wells. Dinoflagellates and pollen yield a Maastrichtian age.
If the Steel Creek is the same age as the redefined Pee Dee (Soh1 and Owens, 1991), it correlates with the middle and upper Ripley and Providence Formations of Georgia and Alabama." The Steel Creek Formation is overlain disconformably by the Paleocene (Midwayan) undifferentiated Black Mingo Formation and, therefore, is older than Paleocene age. TR92-4 TR92-6 USGS Girard VSC-4 Snapp Formation GGS number GGS-3758 Definition Thickness in feet 68 %/a"-not applicable GGS-3782 GGS-3794 n/a n/a The Snapp Formation was named by Fallaw and Price (1992, 1995) for a distinctive, subsurface, lower Tertiary kaolin and sand formation that underlies SRS. It is recognized in Burke, Screven, and Jefferson Counties, Georgia. In eastern Burke County, the Snapp 119 90 78 135+ Formation appears to consist of one fining upward sequence capped with a strongly pigmented, hard, hadsly kaolin with irregular fracture. The mottled kaolin is found in eighteen out of nineteen cores from Burke, Richmond and Jefferson Counties, Georgia, and western Barnwell and Allendale Counties, South Carolina.
The kaolin bed, therefore, appears to be a useful marker bed across that entire area. The Snapp Formation is included here in the Oconee Group. The Snapp Formation in Georgia has not generally been recognized as a separate and distinct lithostratigraphic unit. LeGrand and Furcron (1956) and Henick (1961) included it in the Tuscaloosa Formation and Huddlestun (1981) and Bechtel (1982) included it in the Huber Formation.
In South Carolina, the Snapp has been called the Williamsburg Formation by Colquhoun and others (1983), Steele (1985) and McClelland (1987). Type Locality The Snapp Formation is named for an old railroad stop in the southeastern part of SRS (Fallaw and Price, 1992). The type locality of the Snapp Formation is the site of the core (and water well) P 22TA in SRS (Fallaw and Price, 1992, 1995). The type section, or unit-stratotype (holostratotype), of the formation is the interval 310 feet to 360 feet in core P 22TA. Three Georgia cores and one South Carolina core (Table 5) have been designated as reference localities for the Snapp Formation in the Tritium Project study area (Figure 2). Table 4 Thickness variations for Steek Creek Formation.
Core Site GGS number thickness In feet USGS Millers Pond GG5-3758 68 TR92-4 GG5-3782 119 TR92-6 GG5-3794 90 USGS Girard nla 78 VSC-4 nla 135+""n/a-not applicable Age The Steel Creek Formation is mostly nonfossiliferous.
Samples from the few, thin carbonaceous intervals of the formation in Georgia are barren of pollen so no direct biostratigraphic information is available.
However, in terms of stratigraphic position and physical correlation, the Steel Creek Formation stratigraphically overlies the Campanian (Tayloran)
Gaillard Formation which suggests that the Steel Creek may be early Maastrichtian (early Navarroan) in age.According to Fallaw and Price (1995);Wood fragments, spores, pollen, and rare dinoflagellates have been found in the SRS wells.Dinoflagellates and pollen yield a Maastrichtian age.If the Steel Creek is the same age as the redefined Pee Dee (Sohl and Owens, 1991), it correlates with the middle and upper Ripley and Providence Formations of Georgia and Alabama." The Steel Creek Formation is overlain disconformably by the Paleocene (Midwayan) undifferentiated Black.Mingo Formation and, therefore, is older than Paleocene age.Snapp Formation Definition The Snapp Formation was named by Fallaw and Price (1992, 1995)for a distinctive, subsurface, lower TertiaIy kaolin and sand formation that underlies SRS.It is recognized in Burke, Screven, and Jefferson Counties, Georgia.In eastern Burke County, the Snapp Formation appears to consist of one fining upward sequence capped with a strongly pigmented, hard, hackly kaolin with irregular fracture.The mottled kaolin is found in eighteen out of nineteen cores from Burke, Richmond and Jefferson Counties, Georgia, and western Barnwell and Allendale Counties, South Carolina.The kaolin bed, therefore, appears to be a useful marker bed across that entire area.The Snapp Formation is included here in the Oconee Group.The Snapp Formation in Georgia has not generally been recognized as a separate and distinct lithostratigraphic unit.LeGrand and Furcron (1956)and Herrick.(1961)included it in the Tuscaloosa Formation and Huddlestun (1981)and Bechtel (1982)included it in the Huber Formation.
In South Carolina, the Snapp has been called the Williamsburg Formation by Colquhoun and others (1983), Steele (1985)and McClelland (1987).Type Locality The Snapp Formation is named for an old railroad stop in the southeastern part of SRS (Fallaw and Price, 1992).The type locality of the Snapp Formation is the site of the core (and water well)P 22TA in SRS (Fallaw and Price, 1992,1995).
The type section, or unit-stratotype (holostratotype), of the formation is the interval 310 feet to 360 feet in core P 22TA.Three Georgia cores and one South Carolina core (Table 5)have been designated as reference localities for the Snapp Formation in the Tritium Project study area (Figure 2).17 Savannah River Site Contour interval 20 feet Core site*N Figure 7.Structure contour map of the top of the Steel Creek Formation.
Elevations are in feet relative to mean sea level.Modified from Summerour and others (1994).
Table 5 S~DD Formation reference sections in the Savannah River area. . . The USGS Millers Pond core was chosen as a reference section because it contains typical Snapp lithologies and is clearly overlain disconformably by the Congaree Formation and is underlain with apparent disconformity by the undifferentiated Black Mingo Formation (to be discussed in the following section). Core TR92-2 is chosen as a Snapp Formation reference section because: 1.) it displays the typical single fining upward sequence; 2.) the highly pigmented kaolin and the '%leachedu zone at the top of the formation is present; 3.) the lower kaolinitic, micaceous, poorly sorted coarse sand in the lower part is well-developed; and 4.) there was moderately good (72%) core recovery within the formation.
Core TR92-4 is chosen as a reference section because: 1.) it displays well the "bleached" zone with burrows at the top of the kaolin; 2.) spherical "ooids" or "pellets" that are locally common within the kaolin component of the formation; 3.) the entire Snapp section is distinctive and consists of kaolin without any sand beds; 4.) Planolithes are present at 228 to 229 feet (also see Schroder, 1982); and 5.) the contact with the underlying undifferentiated Black Mingo Formation is apparently gradational. In the Bechtel core VSC-4, from South Carolina (Figure 2), the entire Snapp Formation consists of kaolin and the lower part of the Snapp is gradational over approximately two feet into a gray, hard, siliceous clay and claystone (Williamsburg Formation of the Black Mingo Group (Figure 4). The claystone is in a stratigraphically intermediate position to, and is gradational with, the overlying Snapp Formation and the underlying sand (Rhems Formation
(?) - - - - - VSW n/a of the Black Mingo Group). Core recovery between the Williamsburg and the Snapp is 100%. There is no evidence for disconformity.
Core Slts USGS Millers Pond TR92-2 TR92-4 Lithology GGS core numbers GGS-3758 GGS-3762 GGS-3782 Site Elevation above Mean Sea Level (feet) 245 285 192 'n/aU-not applicable - - - - - 165 322 The Snapp Formation commonly consists of one fining upward sequence in Georgia. In all cores but one in Burke County (GGS McBean), there is a bed of kaolin of varying thickness in the upper part of the formation, the top several feet of which are "bleached".
In two cores (TR92-4) in Georgia and VSC-4 in South Carolina) the entire section consists of kaolin. Elsewhere, the lower part of the formation is a sand. The kaolin is variably silty and finely micaceous. Fine-grained pyrite commonly occurs in burrows, along joints or in irregular concentrations near the top of the Snapp. Very fine grained pyrite is found elsewhere scattered in the formation.
Fine limonite-hematite" and kaolin "ooids" or "pellets" (about 1 mm to 2 mm across) are scattered throughout the upper part of the kaolin in several cores. The kaolin generally is massive-bedded and structureless but some intervals are crudely stratified. The Snapp kaolin is characteristically hackly with irregular fracture and is generally hard and tough when dry.
Slickensided joints are common. Less silty intervals of the kaolin are soapy or waxy to the touch. As previously mentioned, the trace-fossil Planolithes sp. occurs in the interval 228 to 229 feet in core TR92-4. The few feet of burrowed and pyritic kaolin at the top of the section is generally white (N 9) and appears to be '%leached".
The rest of 377.5 Top of formation-fed below surhlce 165 330 231 Bottom of formdon- feet below surface 236 386 282 Table 5 Snapp Formation reference sections in the Savannah River area.Core SIte GGS Site Top of Bottom of core Elevation formatlon-formation-numbers abOve Mean Sea feet below feet below surface Level (feet)surface USGS Millers Pond GG5-3758 245 165 236 TR92-2 GG5-3762 285 330 386 TR92-4 GG5-3782 192 231 282 VSC-4 nfa 165 322 3n.S"n/a-not appllcaDle The USGS Millers Pond core was chosen as a reference section because it contains typical Snapp lithologies and is clearly overlain disconformably by the Congaree Formation and is underlain with apparent disconformity by the undifferentiated Black Mingo Formation (to be discussed in the following section).Core TR92-2 is chosen as a Snapp Formation reference section because: 1.)it displays the typical single fining upward sequence;2.)the highly pigmented kaolin and the"bleached" zone at the top of the formation is present;3.)the lower kaolinitic, micaceous, poorly sorted coarse sand in the lower part is well-developed; and 4.)there was moderately good (72%)core recovery within the formation.
Core TR92-4 is chosen as a reference section because: 1.)it displays well the"bleached" zone with burrows at the top of the kaolin;2.)spherical"ooids" or"pellets" that are locally common within the kaolin component of the formation; 3.)the entire Snapp section is distinctive and consists of kaolin without any sand beds;4.)Planolithes are present at 228 to 229 feet (also see Schroder, 1982);and 5.)the contact with the underlying undifferentiated Black Mingo Formation is apparently gradational.
In the Bechtel core VSC-4, from South Carolina (Figure 2), the entire Snapp Formation consists of kaolin and the lower part of the Snapp is gradational over approximately two feet into a gray, hard, siliceous clay and claystone<Williamsburg Formation of the Black Mingo Group (Figure 4).The claystone is in a stratigraphically intermediate position to, and is gradational with, the overlying Snapp Formation and the underlying sand (Rhems Formation19 of the Black Mingo Group).Core recovery between the Williamsburg and the Snapp is 100%.There is no evidence for disconformity.
Lithology The Snapp Formation commonly consists of one fining upward sequence in Georgia.In all cores but one in Burke County (GGS McBean), there is a bed of kaolin of varying thickness in the upper part of the formation, the top several feet of which are"bleached".
In two cores (TR92-4)in Georgia and VSC-4 in South Carolina)the entire section consists of kaolin.Elsewhere, the lower part of the formation is a sand.The kaolin is variably silty and finely micaceous.
Fine-grained pyrite commonly occurs in burrows, along joints or in irregular concentrations near the top of the Snapp.Very fine grained pyrite is found elsewhere scattered in the formation.
Fine"limonite-hematite" and kaolin"ooids" or"pellets" (about 1 mm to 2 mm across)are scattered throughout the upper part of the kaolin in several cores.The kaolin generally is massive-bedded and structureless but some intervals are crudely stratified.
The Snapp kaolin is characteristically hackly with irregular fracture and is generally hard and tough when dry.Slickensided joints are common.Less silty intervals of the kaolin are soapy or waxy to the touch.As previously mentioned, the trace-fossil Planolithes sp.occurs in the interval 228 to 229 feet in core TR92-4.The few feet of burrowed and pyritic kaolin at the top of the section is generally white (N 9)and appears to be"bleached".
The rest of the kaolin is irregularly mottled &th some highly pigmented, thread-like veins. Pigmentation of the Snapp kaolin ranges through several shades of red, reddish brown, purple, gray, orange, and rarely olive. Neutral hues range from light gray to white. The kaolin of the Snapp Formation generally grades downward into the sand, but locally, the contact is very sharp, having the appearance of a diastem.
The transitional lithology contains common to abundant, and fine- to coarse-grained mica and interstitial kaolin. The sand size ranges from fine-to very fine grained and well-sorted to medium- to coarse-grained and moderately sorted. Some intervals are distinctly strased whereas others are massive-bedded and structureless.
The lower sand of the Snapp Formation is very finely to coarsely micaceous. Kaolin is mostly interstitial but there are rare and scattered beds of thin, carbonaceous clay with plant impressions.
Quartz pebbles are found at the base of the formation in some cores and, less commonly, are scattered throughout the sand section. Dark minerals, fine-grained pyrite, and sulphur-bloom on the core surfaces are sporadic.
Sand size and sand sorting ranges from very fine and well-sorted to very coarse grained and poorly sorted. The sand is massively bedded and structureless, but thinly bedded kaolinitic sand also occurs in scattered sections.
The sand is generally firm, but it is rarely soft and incoherent.
Unliie the kaolin, the sand is not pigmented but is very light gray to white. Stratigraphic Relationships The Snapp Formation underlies all of eastern Burke County, Georgia and is present in the subsurface in the vicinity of Wrens, Jefferson County, Georgia.
Its full aerial extent in eastern Georgia and western South Carolina is not yet known due to insufficient subsurface data. It does not, however, exist as far west as the kaolin mining district in the central Georgia Coastal Plain, nor is it known to exist in outcrop in the kaolin mining district in Aiken County, South Carolina. However, because the Black Mingo is thought to be exposed in some deep creek valleys in southern Aiken County, the overlying Snapp Formation may also crop out. In all cores of eastern Georgia and adjacent Allendale County, South Carolina, the Snapp Formation appears to grade downward into the undifferentiated Black Mingo Formation.
Although some of the Snapp-Black Mingo contacts appear to be disconformable, having basal coarse sands containing pebbles, we think these disconformable contacts are due to channel scour from a prograding, fluvial environment.
A few of the cores have good recovery across the contact and display gradation and conformity over 1 to 2 feet. The stratigraphic interpretations of these gradational contacts are considered to be more reliable because sharp "disconformities" may occur at the base of channels in any formation of coastal marine to fluvial origin. In contrast, the upper contact of the Snapp is strongly disconformable, exhibiting irregular, surfaces.
Burrows and joints in the uppermost Snapp Formation are filled with sediment from the overlying Congaree Formation.
The '%leachedn, commonly pyritic zone in the upper several feet of the formation is conspicuous. The Snapp Formation ranges in thickness from 27 feet (8.2 m) updip to 93.5 feet (28.5 m) downdip (Figure 8). Thickness remains constant along strike into South Carolina.
The kaolin bed ranges in thickness from about 11 feet (3.5 m) to 30 feet (9.0 m). Structure contour lines of the upper surface of the Snapp Formation show the characteristic regional southeast dip (Figure 9). In the vicinity of the Pen Branch fault, the structure contours are somewhat subdued, with a small negative anomaly (< 10 feet (3 m)) on the northern (downthrown) block and a more prominent area of positive relief on the southern (upthrown) block. The environment of deposition of the Snapp Formation is interpreted to have been fluvial, of braided stream origin. It could be interpreted, with the available evidence, that the Snapp Formation represents the final withdrawal of the Midwayan sea, and the progradation of fluvial coastal plain environments.
the kaolin is irregularly mottled some highly pigmented, thread-like veins.Pigmentation of the Snapp kaolin ranges through several shades of red, reddish brown, purple, gray, orange, and rarely olive.Neutral hues range from light gray to white.The kaolin of the Snapp Formation generally grades downward into the sand, but locally, the contact is very sharp, having the appearance of a diastem.The transitional lithology contains common to abundant, and fine-to coarse-grained mica and interstitial kaolin.The sand size ranges from fine-to very fine grained and well-sorted to medium-to coarse-grained and moderately sorted.Some intervals are distinctly stratified whereas others are massive-bedded and structureless.
The lower sand of the Snapp Formation is very finely to coarsely micaceous.
Kaolin is mostly interstitial but there are rare and scattered beds of thin, carbonaceous clay with plant impressions.
Quartz pebbles are found at the base of the formation in some cores and, less commonly, are scattered throughout the sand section.Dark minerals, fine-grained pyrite, and sulphur-bloom on the core surfaces are sporadic.Sand size and sand sorting ranges from very fine and well-sorted to very coarse grained and poorly sorted.The sandismassively bedded and structureless, but thinly bedded kaolinitic sand also occurs in scattered sections.The sand is generally firm, but it is rarely soft and incoherent.
Unlike the kaolin, the sand is not pigmented but is very light gray to white.Stratigraphic Relationships The Snapp Formation underlies all of eastern Burke County, Georgia and is present in the subsurface in the vicinity of Wrens, Jefferson County, Georgia.Its full aerial extent in eastern Georgia and western South Carolina is not yet known due to insufficient subsurface data.It does not, however, exist as far west as the kaolin mining district in the central Georgia Coastal Plain, nor is it known to exist in outcrop in the kaolin mining district in Aiken County, South Carolina.However, because the Black Mingo is thought to be exposed in some deep 20 creek valleys in southern Aiken County, the overlying Snapp Formation may also crop out.In all cores of eastern Georgia and adjacent Allendale County, South Carolina, the Snapp Formation appears to grade downward into the undifferentiated Black Mingo Formation.
Although some of the Snapp-Black Mingo contacts appear to be disconformable, having basal coarse sands containing pebbles, we think these disconformable contacts are due to channel scour from a prograding, fluvial environment.
A few of the cores have good recovery across the contact and display gradation and conformity over 1 to 2 feet.The stratigraphic interpretations of these gradational contacts are considered to be more reliable because sharp"disconformities" may occur at the base of channels in any formation of coastal marine to fluvial origin.In contrast, the upper contact of the Snapp is strongly disconformable, exhibiting irregular, surfaces.Burrows and joints in the uppermost Snapp Formation are filled with sediment from the overlying Congaree Formation.
Thebleached, commonly pyritic zone in the upper several feet of the formation is conspicuous.
The Snapp Formation ranges in thickness from 27 feet (8.2 m)updip to 93.5 feet (28.5 m)downdip (Figure 8).Thickness remains constant along strike into South Carolina.The kaolin bed ranges in thickness from about 11 feet (3.5 m)to 30 feet (9.0 m).Structure contour lines of the upper surface of the Snapp Formation show the characteristic regional southeast dip (Figure 9).In the vicinity of the Pen Branch fault, the structure contours are somewhat subdued, with a small negative anomaly<<10 feet (3 m>>on the northern (downthrown) block and a more prominent area of positive relief on the southern (upthrown) block.The environment of deposition of the Snapp Formation is interpreted to have been fluvial, of braided stream origin.It could be interpreted, with the available evidence, that the Snapp Formation represents the final withdrawal of the Midwayan sea, and the progradation of fluvial coastal plain environments.
Savannah River Site 5 miles o Contour interval 20 feet Core site*5 N Figure 8.Snapp Formation isopach (thickness distribution) map.Thicknesses are in feet.Modified from Summerour and others (1994).
Savannah River Site 5 miles o Contour interval 20 feet Core site.5 N Figure 9.Structure contour map of the top oftheSnapp Formation.
Elevations are in feet relative to mean sea level.
Coastal Plain were significantly different from that of the southern Atlantic Coastal Plain. In South Carolina, Fallaw and Price (1995) considered the Snapp Formation to be Late Paleocene in age: "Fossils are mre in the Snapp. There are not many age determinations, but judging from a few palynological assemblages, and well-dated strata above and below, the unit is probably zone NP9, middle Sabinian, perhaps correlating with the upper part of the Williamsburg Formation (Van Nieuwenhuise and Colquhoun, 1982; Colquhoun, et al, 1983) of eastern South Carolina.
It appears to correlate with the Tuscahorna Sand and perhaps the upper parts of the Nanafalia and Baker Hill (Gibson, 1982) formations of the Gulf Coastal Plain (middle Sabiniarr; upper Thanetian or Selandian)." Based in part on the broadly gradational lower contact with the underlying Midwayan Black Mingo Formation at some sites, and in part on a late Midwayan, Upper Paleocene (Selandian) (Naheola-equivalent) age of the uppermost Black Mingo (Edwards, personal communication, 1995), the most likely age for the Snapp Formation in the Savannah River area is late Midwayan, early Late Paleocene, Selandian.
There is no evidence for an early Sabinian, Thanetian age for the Snapp Formation in Georgia, nor have any deposits of Sabinian age been identified in Burke County. In the eastern Gulf Coastal Plain, the most severe fall in sea level during the Paleocene occurred near the end of the Early Paleocene, Midwayan (pre-Nanafalia)
Stage. This regression and low stand of the sea resulted in the deposition of the basal Gravel Creek Member of the Nanafalia Formation in Alabama (LaMoreaux and Toulmin, 1959), and development of karat topography on the top of the Clayton Formation in the Chattahoochee River area (Toulmin and LaMoreaux, 1963; Marsalis and Friddell, 1975; Reinhardt and Gibson, 1981). The two apparently severe low stands of the sea, the post-Midway-pre-Nanafalia event of the eastern Gulf Coastal Plain and the post-Snapp event in the Savannah River area, are considered here to be contemporaneous.
If they were not, the tectonics of the eastern Gulf Undifferentiated Black Mingo Formation Definition The undifferentiated Black Mingo Formation in eastern Burke County, as defined in this report, is a variably carbonaceous and lignitic, fine- to medium-grained, moderately to well-sorted sand with scattered beds or lenses of gray to black, thinly stratified to laminated clay. It is easily identified in cores and well-cuttings because it is sandwiched between white to mottled kaolinitic sands (overlying Snapp Formation) and white to mottled sandy kaolins (underlying Steel Creek Formation). The sands of the undifferentiated Black Mingo compose the locally restricted Millers Pond aquifer (Figure 3) (Falls and Baum, 1995). In its type area in the central Coastal Plain of South Carolina, the Black Mingo has been elevated to group status (Van Nieuwenhuise and Colquhoun, 1982) with a lower Rhems Formation (divided into two members) and an upper Williamsburg Formation (also divided into two members).
The lower Black Mingo Rhems Formation consists mainly of sandy clay, and the upper Black Mingo Williamsburg Formation is predominantly a siliceous claystone.
The lower Black Mingo is Midwayan in age, and the upper Black Mingo is early Sabinian in age. Because the lower Black Mingo is mainly a clay and the upper Black Mingo is a claystone, and because there is no Sabinian Black Mingo in Burke County, Georgia, the precise stratigraphic relationships between the Black Mingo in its type area and the Burke County Black Mingo is not clear. However, the unit in Burke County is lithologically closely related to the Black Mingo and, therefore, is included in that lithostratigraphic unit as undifferentiated Black Mingo. In the past, the undifferentiated Black Mingo in Burke County has been called Ellenton Formation.
For a discussion on the historical Age In South Carolina, Fallaw and Price (1995)considered the Snapp Formation to be Late Paleocene in age: "Fossils are rare in the Snapp.There are not many age determinations, but judging from a few palynological assemblages, and well-dated strata above and below, the unit is probably zone NP9, middle Sabinian, perhaps correlating with the upper part of the Williamsburg Formation (Van Nieuwenhuise and Colquhoun, 1982;Colquhoun, et aI, 1983)of eastern South Carolina.It appears to correlate with the Tuscahoma Sand and perhaps the upper parts of the Nanafalia and Baker Hill (Gibson, 1982)formations of the Gulf Coastal Plain (middle Sabinian;upper Thanetian or Selandian).
" Based in part on the broadly gradational lower contact with the underlying Midwayan Black Mingo Formation at some sites, and in part on a late Midwayan, Upper Paleocene (Selandian)(Naheola-equivalent) age of the uppermost Black Mingo (Edwards, personal communication, 1995), the most likely age for the Snapp Formation in the Savannah River area is late Midwayan, early Late Paleocene, Selandian.
There is no evidence for an early Sabinian, Thanetian age for the Snapp Formation in Georgia, nor have any deposits of Sabinian age been identified in Burke County.In the eastern Gulf Coastal Plain, the most severe fall in sea level during the Paleocene occurred near the end of the Early Paleocene, Midwayan (pre-Nanafalia)
Stage.This regression and low stand of the sea resulted in the deposition of the basal Gravel Creek Member of the Nanafalia Formation in Alabama (LaMoreaux and Toulmin, 1959), and development of karst topography on the top of the Clayton Formation in the Chattahoochee River area (Toulmin and LaMoreaux, 1963;Marsalis and Friddell, 1975;Reinhardt and Gibson, 1981).The two apparently severe low stands ofthe sea, the post-Midway-pre-Nanafalia event of the eastern Gulf Coastal Plain and the post-Snapp event in the Savannah River area, are considered here to be contemporaneous.
If they were not, the tectonics of the eastern Gulf 23 Coastal Plain were significantly different from that of the southern Atlantic Coastal Plain.Undifferentiated Black Mingo Formation Definition The undifferentiated Black Mingo Formation in eastern Burke County, as defined in this report, is a variably carbonaceous and lignitic, fine-to medium-grained, moderately to well-sorted sand with scattered beds or lenses of gray to black, thinly stratified to laminated clay.It is easily identified in cores and well-cuttings because it is sandwiched between white to mottled kaolinitic sands (overlying Snapp Formation) and white to mottled sandy kaolins (underlying Steel Creek Formation)
..The sands of the undifferentiated Black Mingo compose the locally restricted Millers Pond aquifer (Figure 3)(Falls and Baum, 1995).In its type area in the central Coastal Plain of South Carolina, the Black Mingo has been elevated to group status (Van Nieuwenhuise and Colquhoun, 1982)with a lower Rhems Formation (divided into two members)and an upper Williamsburg Formation (also divided into two members).The lower Black Mingo Rhems Formation consists mainly of sandy clay, and the upper Black Mingo Williamsburg Formation is predominantly a siliceous claystone.
The lower Black Mingo is Midwayan in age, and the upper Black Mingo is early Sabinian in age.Because the lower Black Mingo is mainly a clay and the upper Black Mingo is a claystone, and because there is no Sabinian Black Mingo in Burke County, Georgia, the precise stratigraphic relationships between the Black Mingo in its type area and the Burke County Black Mingo is not clear.However, the unit in Burke County is lithologically closely related to the Black Mingo and, therefore, is included in that lithostratigraphic unit as undifferentiated Black Mingo.In the past, the undifferentiated Black Mingo in Burke County has been called Ellenton Formation.
For a discussion on the historical review and relationship of the Black Mingo and Ellenton Formations, see Appendix 2. The type locality of the Black Mingo, as assigned by Sloan (1908, p. 4/52), is at Perkins Bluff on the Black River near the confluence of the Black River with Black Mingo Creek. Sloan (1908) recognized both a lower and upper Black Mingo and the Black %go exposed at Perkins Bluff is lower Black Mingo. However, it is not clear from the text whether Sloan (1908) intended Perkins Bluff to be the type locality for the entire Black Mingo phase or whether he intended Perkins Bluff to be the type locality only for the lower Black Mingo. He did not assign a type locality to the upper Black %go. We conclude, therefore, on the basis of default and original designation, that the type locality of the Black Mingo Formation must be at Perkins Bluff on the Black River. The section of Black Mingo exposed at Perkins Bluff is therefore, the type section, or unit-stratotype (holostratotype) of the Black Mingo Formation (Group). Perkins Bluff on the Black River is in Georgetown County, South Carolina, 10 miles northeast of Harpers and about three miles west of Rope Ferry (Sloan, 1908, p. 452, 360). For the Savannah River area, we propose that the core from the monitoring well P-18, taken less than 10 feet from the site of the well 524, the type locality of the Ellenton Formation of Siple (1967) be considered a reference ldty and reference section (ledostratotype) for the undifferentiated Black Mingo Formation.
The surface elevation of the core P-18 is 354 feet above sea level and the elevation of the top of the Ellenton is at 260 feet in the core (104 feet above sea level). Useful reference sections (hypostratotypes) of the undifferentiated Black Mingo Formation in Burke County, Georgia are listed in Table 6. The core sites (Figure
- 2) are described in Appendix 1 and the coordinates are listed in Table 1. The GGS McBean core was chosen as a hypostratotype because it is the only core in northern (northern-most) Burke County where the undifferentiated Black Mingo is clearly divisible into an upper and lower part. The upper part is a conspicuously glauconitic sand and the lower part is a resistant, hackly, dark gray clay. TR92-3 is designated as a reference locality for the Black Mingo Formation in central eastern Burke County because it is characteristic of the formation in northern Burke County and because the core recovery in the formation was good (-77%). The Black Mingo in this core is overlain with an apparent diadem by the Snapp Formation.
Core TR92-6 is designated as a reference locality because it is characteristic of the undifferentiated Black Mingo Formation in northern Burke County, consisting of apprcdmately 87% sand beds and 13% clay beds. Core recovery through the undifferentiated Black %go was good in the core (- 73%). The undifferentiated Black Mingo Formation in core TR92-6 overlies the Steel Creek Formation with a clear disconformity and is overlain paraconformably by the Congaree Formation. The USGS Gi core was chosen as a hyposhatotype because the Black Mingo Formation in this core has a lower and upper part and resembles the lithologic descriptions of the Rhems, Williamsburg, and Lang Syne lithologies in the type area in South Carolina.
Core VG-6 is designated as a reference locality because it is lithologically characteristic of the formation in southern Burke County, and because there is a distinction between an upper and lower part. However, the distinction is less obvious than in the Girard core. Bechtel core VSC4 is chosen because it is lithologically characteristic of the formation in western Allendale County, South Carolina, and because the Black Mingo is overlain gradationally by the Williamsburg Formation, a stratigraphic juxtaposition that does not exist in Burke County. The Black Mingo Formation also is characteristically sandier in South Carolina near the Barnwell-Allendale County line than across the Savannah River in Burke County. Lithology In Burke County, Georgia, sand is the dominant lithic component of the undiffer-entiated Black %go Formation but clay is review and relationship of the Black Mingo and Ellenton Formations, see Appendix 2.Type Locallty The type locality of the Black Mingo, as assigned by Sloan 0908, p.452), is at Perkins Bluft'on the Black River near the confluence of the Black River with Black Mingo Creek.Sloan (908)recognized both a lower and upper Black Mingo and the Black Mingo exposed at Perkins Bluft'is lower Black Mingo.However, it is not clear from the text whether Sloan (908)intended Perkins Bluft'to be the type locality for the entire Black Mingo phase or whether he intended Perkins Bluft'to be the type locality only for the lower Black Mingo.He did not assign a type locality to the upper Black Mingo.We conclude, therefore, on the basis of default and original designation, that the type locality of the Black Mingo Formation must be at Perkins Bluft'on the Black River.The section of Black Mingo exposed at Perkins Bluft'is therefore, the type section, or unit-stratotype (holostratotype) of the Black Mingo Formation (Group).Perkins Bluft'on the Black River is in Georgetown County, South Carolina, 10 miles northeast of Harpers and about three miles west of Rope Ferry (Sloan, 1908, p.452, 360).For the Savannah River area, we propose that the core from the monitoring well P-18, taken less than 10 feet from the site of the well 52-C, the type locality of the Ellenton Formation of Siple (1967)be considered a reference locality and reference section Oectostratotype) for the undifferentiated Black Mingo Formation.
The surface elevation of the core P-18 is 354 feet above sea level and the elevation of the top of the Ellenton is at 250 feet in the core (104 feet above sea level).Useful reference sections (hypostratotypes) of the undifferentiated Black Mingo Formation in Burke County, Georgia are listed in Table 6.The core sites (Figure 2)are described in Appendix 1 and the coordinates are listed in Table 1.The GGS McBean core was chosen as a hypostratotype because it is the only core in northern (northern-most)
Burke County where 24 the undifferentiated Black Mingo is clearly divisible into an upper and lower part.The upper part is a conspicuously glauconitic sand and the lower part is a resistant, hack1y, dark gray clay.TR92-3 is designated as a reference locality for the Black Mingo Formation in central eastern Burke County because it is characteristic of the formation in northern Burke County and because the core recovery in the formation was good (-77%).The Black Mingo in this core is overlain with an apparent diastem by the Snapp Formation.
Core TR92-6 is designated as a reference locality because it is characteristic of the undifferentiated Black Mingo Formation in northern Burke County, consisting of approximately 87%sand beds and 13%clay beds.Core recovery through the undifferentiated Black Mingo was good in the core (-73%).The undifferentiated Black Mingo Formation in core TR92-6 overlies the Steel Creek Formation with a clear disconformity and is overlain paraconformably by the Congaree Formation.
The USGS Girard core was chosen as a hypostratotype because the Black Mingo Formation in this core has a lower and upper part and resembles the lithologic descriptions of the Rhems, Williamsburg, and Lang Syne lithologies in the type area in South Carolina.Core VG-6 is designated as a reference locality because it is lithologically characteristic of the formation in southern Burke County, and because there is a distinction between an upper and lower part.However, the distinction is less obvious than in the Girard core.Bechtel core VSC-4 is chosen because it is lithologically characteristic of the formation in western Allendale County, South Carolina, and because the Black Mingo is overlain gradationally by the Williamsburg Formation, a stratigraphic juxtaposition that does not exist in Burke County.The Black Mingo Formation also is characteristically sandier in South Carolina near the Barnwell-Allendale County line than across the Savannah River in Burke County.Lithology In Burke County, Georgia, sand is the dominant lithic component of theentiated Black Mingo Formation but clay is TaMe 6 Undifferentiated Black Mingo Formation reference sections.
11 GGS McBean I GGS-3757 ( 297 272 I 299 I I I SRS P-18' I 'n/an-~ot applicable or not available Core Stte ma Flgure 2 Table 1 1. Not in area covered by flgure 2 map. Top of formation-feet bekw rurface n/a ubiquitous.
Clay occurs both interstitially and in thin and, rarely, thick beds. The gray to black clays in the upper part of the formation probably are dominantly smectitic but kaolin occurs in updip, lower beds of the formation.
A thin bed of claystone (0.1 foot thick), virtually identical to the Williamsburg Formation, in Barnwell and Allendale Counties, S.C., is present in the middle of the unwerentiated Black Mingo in core VG-4. Carbonaceous material, including lignite flecks, fragments and scattered thin beds of lignite are characteristic of the Black Mingo Formation in Burke County, GGS core number Bottom of formatlon-tea below surface pebbly, poorly sorted sand, at the base of the Black Mingo in some cores in northern Burke County, is similar to the Sawdust Landing Formation of SRS of Fallaw and Price (1992, 1995). Sorting ranges from very well-sorted to very poorly sorted. In some cores, (e.g., VG-3), the grain-size is relatively coarse (medium- grained) and the sorting is relatively poor (moderately to moderately poorly sorted). Sand is mostly incoherent to barely coherent and soft. However, the degree of induration or consolidation of the sand ranges from incoherent, soft and disturbed to very Sb Elovalion above M.an !%a bvel (fw 354 and are present in all cores that penetrate the coherent, tough, and slightly indurated but formation.
Other lithic components include fine friable. Hard, pyrite or silica-cemented (common) to coarse mica (rare), dark minerals, sandstone is rare. Sand color ranges from white scattered glauconite, scattered pyrite and rare to light-gray, shades of brown, and olive gray to pyrite-cemented sandstone, both acicular and olive black. cauliflower-like gypsum-bloom on core surfaces, Clay beds are variably silty and finely to some sulphur-bloom on core surfaces, rare and local phosphatic vertebrate debris and a trace of pelletal phosphate in southernmost Burke County, rare interstitial silica(?)
in sandstones, traces of feldspar, thin limestone beds, and calcareous macro- and microfossiliferous beds in southernmost Burke County. Black Mingo sand in Burke County is most commonly medium- to fine-grained and moderately to well-sorted, but may range from very fine to coarse-grained, with local occurrences of pea-gravel.
Coarse to granular; 250 coarsely micaceouq variably carbonaceous and lignitic, with rare and scattered thin beds of lignite, rare carbonaceous leaf prints on bedding planes or partings, and carbon films on bedding planes. Common to abundant sulphur- and gypsum-bloom occurs on the surfaces of the cores. Sand content of the clay is variable.
The clay and fine sand layers are of varying thicknesses, ranging from thinly interbedded fine sand and clay, to interlaminated very fine sand and clay, to laminated silty clay. Bedding is generally thin to laminated, fissile and papery, n/a Table 6 Undifferentiated Black Mingo Formation reference sections.Core SIte GGS Site Elevation Top of formation-feet Bottom of formatlon-He Figure 2 core above below surface feet below surface Table 1 number Mean Sea Level (feet)SAS P.18 1 nja 354 250 nja TFl92-3 GGS-3781 195 290 370 TR92-6 GGS-3794 240 274 324 GGS McBean GGS-3757 297 272 299 USGS Girard nja 250 482 542 VSG-4 nja 156.5 3n.5 494 VG-6 nja 217 522 588 n/a-Not applicable or not available 1.Not in area covered by Agure 2 map.ubiquitous.
Clay occurs both interstitially and in thin and, rarely, thick beds.The gray to black clays in the upper part of the formation probably are dominantly smectitic but kaolin occurs in up dip, lower beds of the formation.
A thin bed of claystone (0.1 foot thick), virtually identical to the Williamsburg Formation, in Barnwell and Allendale Counties, S.C., is present in the middle of the undifferentiated Black Mingo in core VG-4.Carbonaceous material, including lignite flecks, fragments and scattered thin beds of lignite are characteristic of the Black Mingo Formation in Burke County, and are present in all cores that penetrate the formation.
Other lithic components include fine (common)to coarse mica (rare), dark minerals, scattered glauconite, scattered pyrite and rare pyrite-cemented sandstone, both acicular and cauliflower-like gypsum-bloom on core surfaces, some sulphur-bloom on core surfaces, rare and local phosphatic vertebrate debris and a trace of pelletal phosphate in southernmost Burke County, rare interstitial silica(?)in sandstones, traces of feldspar, thin limestone beds, and calcareous macro-and microfossiliferous beds in southernmost Burke County.Black.Mingo sand in Burke County is most commonly medium-to fine-grained and moderately to well-sorted, but may range from very fine to coarse-grained, with local occurrences of pea-gravel.
Coarse to granular;25 pebbly, poorly sorted sand, at the base of the Black Mingo in some cores in northern Burke County, is similar to the Sawdust Landing Formation of SRa of Fallaw and Price (1992, 1995).Sorting ranges from very well-sorted to very poorly sorted.In some cores, (e.g., VG-3), the grain-size is relatively coarsegrained)and the sorting is relatively poor (moderately to moderately poorly sorted).Sand is mostly incoherent to barely coherent and soft.However, the degree of induration or consolidation of the sand ranges from incoherent, soft and disturbed to very coherent, tough, and slightly indurated but friable.Hard, pyrite or silica-cemented sandstone is rare.Sand color ranges from white to light-gray, shades of brown, and olive gray to olive black.Clay beds are variably silty and finely to coarsely micaceous, variably carbonaceous and lignitic, with rare and scattered thin beds of lignite, rare carbonaceous leaf prints on bedding planes or partings, and carbon films on bedding planes.Common to abundant sulphur-and gypsum-bloom occurs on the surfaces of the cores.Sand content of the clay is variable.The clay and fine sand layers are of varying thicknesses, ranging from thinly interbedded fine sand and clay, to interlaminated very fine sand and clay, to laminated silty clay.Bedding is generally thin to laminated, fissile and papery, but there are some beds of clay that are massive and structureless.
Clay beds in southernmost Burke County are calcareous and macro- and microfossiliferous.
Carbonaceous clay colors range from black to dark gray, and shades of brown and olive gray. Noncarbonaceous clays range in color from shades of gray (rarely very light gray). Bedding in the Black Mingo ranges from massive and structureless to crudely bedded, faintly bioturbated, and thinly bedded (interlaminated in the clay intervals). There is some undulatory bedding and weakly inclined bedding. In two Bechtel cores in Barnwell and Allendale Counties, South Carolina, a short distance across the Savannah River, the Black Mingo divides into an upper Black Mingo, Williamsburg claystone (or mudstone) lithology and a lower sandy part that resembles the Burke County Black Mingo, but is neither carbonaceous nor lignitic.
The two parts of the formation are gradational.
In the VSC-3 in Barnwell County, the entire Black Mingo stratigraphic interval is 43 feet (13 m) thick, whereas in the VSC-4, the interval is 67 feet (20 m) thick, due in large part to the thicker claystone section in the unit. Stratigraphic Relationships Eastward, at SRS in South Carolina, the stratigraphic equivalent of the undifferentiated Black Mingo Formation of this report is the Ellenton Formation of Siple (19671, the Rhems Formation of Colquhoun and others (1983) and McClelland (1987), and the Sawdust Landing Formation of Muthig and Colquhoun (19881, and Fallaw and Price (1992, 1995). In eastern Burke County the Black Mingo Formation disconformably overlies the Upper Cretaceous Steel Creek Formation of the Oconee Group and gradationally (or paraconformably) underlies the Snapp Formation.
The thickness of the Black Mingo Formation in eastern Burke County, Georgia is unusually variable, ranging from 82 feet (25 m) to 16 feet (4.9 m), a difference of 66 feet (20 m) (Figure 10). This variability in thickness is particularly notable in northern Burke County. The average thickness of the Black Mingo in northern Burke County is approximately 48 feet (15 m). In southern Burke County the range of thickness of the Black Mingo is from 52 feet (16 m) to 24+ feet (7.3+ m). Average thickness of the Black Mingo in southern Burke County is about 38 feet (about 12 m). Thickness of the Black Mingo Formation in southern Burke County is uncertain, however, because there are intervals with no core recovery between the Black Mingo and Snapp Formation in all cores. The direction of dip on the top of the Black Mingo Formation in Burke County is generally to the southeast (Figure 11). However, the angle of dip is variable.
Dip angles range from 15 feet per mile to 26 feet per mile. There is a dip reversal in the vicinity of the Pen Branch fault.
In Burke County the Black Mingo Formation appears to consist of interfingering or interlensed coastal marine and inner neritic, marine, siliciclastic deposits. This interpretation is based on the presence of dinoflagellates which live only in a marine environment.
Dinoflagellates are found throughout the formation across Burke County. Other evidence for marine deposition includes scattered glauconite in the formation throughout Burke County, and a shark tooth in the upper glauconitic sand in the GGS McBean core near McBean Creek in northern Burke County. On the other hand, a sample from 402-405 feet in the core VG-3 contains the freshwater alga Pediustrum, indicating a freshwater iduence even in southern Burke County (Edwards, personal communication, 1995).
The Black Mingo-Snapp stratigraphic interval may represent two depositional episodes in which the lower part of the Black Mingo Formation represents one separate, lower Midwayan (Lower Paleocene, Danian) depositional episode, and the other an upper Midwayan (Upper Paleocene, Selandian) depositional episode (Figure 12). The two depositional episodes are separated by a diastem or paraconformity (Edwards, personal communication, 1995). The Snapp Formation but there are some beds of clay that are massive and structureless.
Clay beds in southernmost Burke County are calcareous and macro-and microfossiliferous.
Carbonaceous clay colors range from black to dark gray, and shades of brown and olive gray.Noncarbonaceous clays range in color from shades of gray (rarely very light gray).Bedding in the Black Mingo ranges from massive and structureless to crudely bedded, faintly bioturbated, and thinly bedded (interlaminated in the clay intervals).
There is some undulatory bedding and weakly inclined bedding.In two Bechtel cores in Barnwell and Allendale Counties, South Carolina, a short distance across the Savannah River, the Black Mingo divides into an upper Black Mingo, Williamsburg claystone (or mudstone)lithology and a lower sandy part that resembles the Burke County Black Mingo, but is neither carbonaceous nor lignitic.The two parts of the formation are gradational.
In the VSC-3 in Barnwell County, the entire Black Mingo stratigraphic interval is 43 feet (13 m)thick, whereas in the VSC-4, the interval is 67 feet (20 m)thick, due in large part to the thicker claystone section in the unit.Stratigraphic Relationships Eastward, at SRB in South Carolina, the stratigraphic equivalent of the undifferentiated Black Mingo Formation of this report is the Ellenton Formation of Siple (1967), the Rhems Formation of Colquhoun and others (1983)and McClelland (1987), and the Sawdust Landing Formation of Muthig and Colquhoun (1988), and Fallaw and Price (1992, 1995).In eastern Burke County the Black Mingo Formation disconformably overlies the Upper Cretaceous Steel Creek Formation of the Oconee Group and gradationally (or paraconformably) underlies the Snapp Formation.
The thickness of the Black Mingo Formation in eastern Burke County, Georgia is unusually variable, ranging from 82 feet (25 m)to 16 feet (4.9 m), a difference of 66 feet (20 m)26 (Figure 10).This variability in thickness is particularly notable in northern Burke County.The average thickness of the Black Mingo in northern Burke County is approximately 48 feet (15 m).In southern Burke County the range of thickness of the Black Mingo is from 52 feet (16 m)to 24+feet (7.3+m).Average thickness of the Black Mingo in southern Burke County is about 38 feet (about 12 m).Thickness of the Black Mingo Formation in southern Burke County is uncertain, however, because there are intervals with no core recovery between the Black Mingo and Snapp Formation in all cores.The direction of dip on the top of the Black Mingo Formation in Burke County is generally to the southeast (Figure 11).However, the angle of dip is variable.Dip angles range from 15 feet per mile to 26 feet per mile.There is a dip reversal in the vicinity of the Pen Branch fault.In Burke County the Black Mingo Formation appears to consist of interfingering or interlensed coastal marine and inner neritic, marine, siliciclastic deposits.This interpretation is based on the presence of dinoflagellates which live only in a marine environment.
Dinoflagellates are found throughout the formation across Burke County.Other evidence for marine deposition includes scattered glauconite in the formation throughout Burke County, and a shark tooth in the upper glauconitic sand in the GGS McBean core near McBean Creek in northern Burke County.On the other hand, a sample from 402-405 feet in the core VG-3 contains the freshwater alga Pediastrum, indicating a freshwater influence even in southern Burke County<Edwards, personal communication, 1995).The Black Mingo-Snapp stratigraphic interval may represent two depositional episodes in which the lower part of the Black Mingo Formation represents one separate, lower Midwayan (Lower Paleocene, Danian)depositional episode, and the other an upper Midwayan (Upper Paleocene, Selandian) depositional episode (Figure 12).The two depositional episodes are separated by a diastem or paraconformity (Edwards, personal communication, 1995).The Snapp Formation Savannah River Site 5 miles o Contour interval 20 feet Core site*5 Figure 10.Undifferentiated Black Mingo Formation isopach(thicknessdistribution) map.Thicknesses are in feet.
Savannah River Site 5 miles o Contour interval 20 feet Core site*5 N Figure 11.Structure contour map of the top of the undifferentiated Black Mingo Formation.
Elevations are in feet relative to mean sea level.
Savannah River Site Contour interval 20 feet Core site.Figure 12.Undifferentiated Black Mingo/Snapp Formations isopach (thickness distribution) map.Thicknesses are in feet.
represents the regressive, falling sea level of the Selandian, Upper Paleocene.
The undifferentiated Black Mingo Formation.in southern Burke County, Georgia is early to late Midwayan in age based on planktonic foraminifera, dinoflagellate assemblages and pollen floras (Edwards, Globorotalia pseudobulloides is early Late Paleocene, and Globorotaliaperclam is especially characteristic of the Early Paleocene, all of Midwayan age, in Georgia. The benthic foraminifer, Eouuigerina excwata, has been reported only from Early Paleocene, Midwayan deposits in the Coastal Plain.
This assemblage is characteristic of, and restricted to, the Clayton and lower Porters Creek Formations of Alabama and western Georgia Edwards (personal communication, 1994) identitied the following dinocysts from a sample at 281 feet in core TR92-6 from Burke County, Georgia: Andalusiella sp. atT. A polymorpha of Edwards (1980) Gordosphaeridium fibrospinosum Glaphyrocysta ordinata weunecysta spp. Operculodinium spp. Palaeocystodinium golzowense Phelodinium sp. of Edwards (1989) Spiniferites spp. small peridiniaceans According to Edwards, "The dinocysts are most probably of the early part of Late Paleocene age, but again ranges are not well established and many forms are unnamed. The environment is marine, but probably not very far offshore." Edwards identified the following dinocysts from a sample at 302 feet in the core TR92-6: Alterbidinium?
- n. sp., near A pentamdiata Areoligera-Cyclonephelium group Cordosphaeridium fibrospinoswn Damassadinium californicum Diphyes colligerum Z Glaphyrocysta reticulosa of Firth (1993) Hystn'chokolpoma cinctum? Hystrichosphaeridiwn tubifem Impagidiniwn?
sp. weunecysta sp. Palaeocystodinium (fat) Phelodinium magnificum s.s. Spiniferites spp. Tectadodinium rugulatum?
small peridiniaceans Edwards concluded that "the dinocysts are most probably of the latter part of Early Paleocene age, but ranges are not well established and many of the forms are unnamed -- so don't be surprised if it tuns out to be early in the Late Paleocene. The environment is marine, but probably not very far offshore." Further, in VG-3, Edwards identified the following dinoflagellate flora from a sample at 459 feet in the Black Mingo Formation:
Alterbidiniwn?
atT. A? pentaradiatum Caligodinium amiculum Palaeoperidinium pymphorum Spinidinium densispinatum Spinidinium pulchm small, pale peridinioids According to Edwards (personal communication, 19941, "The age [of the above floml is Early Paleocene.
The distinctive, but unnamed species, Alterbidinium?
aft: A? gentamdiatum is known from the Brightseat Formation in Mcuyland and the McBryde Limestone Member of the Clayton Formation in Alabama" Edwards identitied the following dinoflagellate flora from the Black Mingo Formation at 423 feet in the core VG-3: Areoligera sp. Cordosphaeridium inodes Danea califonica?
Fibradinium annetorpense Kallosphaeridium sp. Operculodinium centrocarpum Palaeocystodinium golzowense Phelodinium magnificum-group Spinidinium cf. S. densispinatum Spiniferites sp. represents the regressive, falling sea level of the Selandian, Upper Paleocene.
Age The undifferentiated Black Mingo Formation in southern Burke County, Georgia is early to late Midwayan in age based on planktonic foraminifera, dinoflagellate assemblages and pollen floras (Edwards, Globorotalia pseudobulloides is early Late Paleocene, and Globorotalia perclara is especially characteristic of the Early Paleocene, all of Midwayan age, in Georgia.The benthic foraminifer, Eouvigerina exccwata, has been reported only from Early Paleocene, Midwayan deposits in the Coastal Plain.This assemblage is characteristic of, and restricted to, the Clayton and lower Porters Creek Formations of Alabama and western Georgia.Edwards (personal commundcation, 1994)identified the following dinocysts from a sample at 281 feet in core TR92-6 from Burke County, Georgia: Andalusiella sp.aff.A polymorpha of Edwards (1980)Gordosphaeridium fibrospinosum Glaphyrocysta ordinata lRjeunecysta spp.Operculodinium spp.Palaeocystodinium golzowense Phelodinium sp.of Edwards (1989)Spiniferites spp.small peridiniaceans According to Edwards,"The dinocysts are most probably of the early part of Late Paleocene age, but again ranges are not well established and many forms are unnamed.The environment is marine, but probably not very far offshore." Edwards identified the following dinocysts from a sample at 302 feet in the core TR92-6: Alterbidinium?
n.sp., near A pentaradiata Areoligera-Cyclonephelium group Cordosphaeridium fibrospinosum Damassadinium califomicum Diphyes colligerum 30 Glaphyrocysta reticulosa of Firth (1993)Hystrichokolpoma cinctum?Hystrichosphaeridium tubiferum Impagidinium?
sp.lRjeunecysta sp.Palaeocystodinium (fat)Phelodinium magnificum s.s.Spiniferites spp.Tectadodinium rugulatum?
small peridindaceans Edwards concluded thatthe dinocysts are most probably of the latter part of Early Paleocene age, but ranges are not well established and many of the forms are unnamed--so don't be surpri8ed if it turns out to be early in the Late Paleocene.
The environment is marine, but probably not very far offshore." Further, in VG-3, Edwards identified the following dinoflagellate flora from a sample at 459 feet in the Black Mingo Formation:
Alterbidinium?
aff.A?pentaradiatum Caligodinium amiculum Palaeoperidinium pyrophorum Spinidinium densispinatum Spinidinium pulchrum small, pale peridindoids According to Edwards (personal communication, 1994),"The age[of the above floral is Early Paleocene.
The distinctive, but unnamed species, Alterbidinium?
aft.A?pentaradiatum is known from the Brightseat Formation in Maryland and the McBryde Limestone Member of the Clayton Formation in Alabama." Edwards identified the following dinoflagellate flora from the Black Mingo Formation at 423 feet in the core VG-3: Areoligera sp.Cordosphaeridium inodes Danea californica?
Fibradinium annetorpense Kallosphaeridium sp.Operculodinium centrocarpum Palaeocystodinium golzowense Phelodinium magnificum-group Spinidinium cf.S.densispinatum Spiniferites sp.
She concluded that "The age is Paleocene, somewhere in the early or 'mid'pcrrt. " Based on the above microfossil identifications and comments, the Black Mingo Formation in eastern Burke County is early to "middle" Paleocene, entirely Midwayan in age (Figure 4). This corresponds to Early and earliest Late Paleocene, Danian and Selandian age. Most of the formation is Selandian in age. Claiborne Group The name Claiborne was first applied by Conrad (1848a, 184823) to deposits that contain a shelly fauna of similar composition to that of the abundantly fossiliferous deposits exposed at Claiborne Bluff on the Alabama River in Monroe County, Alabama. Smith (1907, p. 17) raised the name Claiborne to group rank and included the Tallahatta buhrstone, Lisbon Formation, and Gosport Greensand in the Claiborne Group. The name Claiborne Group was extended into Georgia by Veatch and Stephenson (1911, p. 235-2961 and subsequent usage of the name in Georgia has been varied (Brantley, 1916; Cooke and Shearer, 1918; MacNeil, 1944a, 1944b, 1947; Herrick, 1961; Marsalis and Friddell, 1975). In this report, the Claiborne Group in Georgia is recognized as a lithostratigraphic unit with the same or similar lithologic characters and stratigraphic position as the Claiborne Group in its type area in southwestern Alabama. It consists of calcareous to noncalcareous, variably fossiliferous, variably glauconitic, argillaceous, fine- to coarse-grained sand with scattered beds of clay, siliceous claystone (buhrstone), and limeatone.
The Claiborne Group consists of three formations in Georgia; the Congaree Formation, Still Branch Sand (new name), and Lisbon Formation.
In outcrop in western Georgia, the Claiborne Group consist8 of the Congaree Formation (Tallahatta Formation of past usage) in the lower part, and the Lisbon Formation in the upper part.
Both the Congaree Formation and Lisbon Formation extend across Georgia from eastern Alabama to the Savannah River in Georgia, however, from the vicinity of the Flint River to the Savannah River, the Congaree and Lisbon Formations are known only as subsurface units. Except for one exposure on lower McBean Creek in Burke County, the Still Branch Sand is entirely a subsurface unit in Georgia. The Congaree Formation is included in the Claiborne Group in this report because of its lithology and stratigraphic position.
It has consistently been called Tallahatta Formation in the Chattahoochee River area since 1947 (MacNeil, 1947% 194713; Toulmin and LaMoreaux, 1963; Marsalis and Friddell, 1975; Reinhardt and Gibson, 1981; Huddlestun, et al, 1988) and, therefore, is an integral part of the concept of the Claiborne Group in Georgia. The Still Branch Sand is included in the Claiborne Group because of its general lithologic similarity to Claiborne Group deposits (i.e., it is a fossiliferous, variably argillaceous, calcareous sand). Undifferentiated Still Branch Sand grades updip into the Bennock Millpond Sand Member. The Bennock Millpond Sand is margixdy a part of the Claiborne Group.
Some of the Bennock Millpond lithofacies (e.g. shell beds) are lithologically much like the Lisbon Formation in southwestern Alabama. However, the stratified, fine-grained, well-sorted sand of the Bennock Millpond is lithologically very similar to the Pew Sand of the Fort Valley Group (Huddlestun and Hetrick, 1991) in central and southwestern Georgia. The upper, outcropping part of the Lisbon Formation
(= Cubitostrea sellaefonnis Zone) in Burke County is divided into two formal members in this report: the Blue Bluff Member and the McBean Limestone Member. An undifferentiated Lisbon sand (Figure
- 5) is also associated with the McBean and Blue Bluff Members in northern Burke County. Type Locality The type locality of the Claiborne Group is the section of Lisbon Formation and Gosport Sand exposed at Claiborne Bluff on the Alabama River in Monroe County, Alabama. She concluded that"The age is Paleocene, somewhere in the early or'mid'part." Based on the above microfossil identifications and comments, the Black Mingo Formation in eastern Burke County is early to"middle" Paleocene, entirely Midwayan in age (Figure 4).This corresponds to Early and earliest Late Paleocene, Danian and Selandian age.Most of the formation is Selandian in age.Claiborne Group Definition The name Claiborne was first applied by Conrad (1848a, 1848b)to deposits that contain a shelly fauna of similar composition to that of the abundantly fossiliferous deposits exposed at Claiborne Bluff on the Alabama River in Monroe County, Alabama.Smith (1907, p.17)raised the name Claiborne to group rank and included the Tallahatta buhrstone, Lisbon Formation, and Gosport Greensand in the Claiborne Group.The name Claiborne Group was extended into Georgia by Veatch and Stephenson (1911, p.235-296)and subsequent usage of the name in Georgia has been varied (Brantley, 1916;Cooke and Shearer, 1918;MacNeil, 1944a, 1944b, 1947;Herrick, 1961;Marsalis and Friddell, 1975).In this report, the Claiborne Group in Georgia is recognized as a lithostratigraphic unit with the same or similar lithologic characters and stratigraphic position as the Claiborne Group in its type area in southwestern Alabama.It consists of calcareous to noncalcareous, variably fossiliferous, variably glauconitic, argillaceous, fine-to coarse-grained sand with scattered beds of clay, siliceous claystone (buhrstone), and limestone.
The Claiborne Group consists of three formations in Georgia;the Congaree Formation, Still Branch Sand (new name), and Lisbon Formation.
In outcrop in western Georgia, the Claiborne Group consists of the Congaree Formation (Tallahatta Formation of past usage)in the lower part, and the Lisbon Formation in the upper part.Both the Congaree Formation and Lisbon Formation extend across Georgia from eastern Alabama to the Savannah River in Georgia, however, from the vicinity of the Flint River to the Savannah 31 River, the Congaree and Lisbon Formations are known only as subsurface units.Except for one exposure on lower McBean Creek in Burke County, the Still Branch Sand is entirely a subsurface unit in Georgia.The Congaree Formation is included in the Claiborne Group in this report because of its lithology and stratigraphic position.It has consistently been called Tallahatta.
Formation in the Chattahoochee River area since 1947 (MacNeil, 1947a, 1947b;Toulmin and LaMoreaux, 1963;Marsalis and Friddell, 1975;Reinhardt and Gibson, 1981;Huddlestun, et al, 1988)and, therefore, is an integral part of the concept of the Claiborne Group in Georgia.The Still Branch Sand is included in the Claiborne Group because of its general lithologic similarity to Claiborne Group deposits (i.e., it is a fossiliferous, variably argillaceous, calcareous sand).Undifferentiated Still Branch Sand grades updip into the Bennock Millpond Sand Member.The Bennock Millpond Sand is marginally a part of the Claiborne Group.Some of the Bennock Millpond lithofacies (e.g.shell beds)are lithologically much like the Lisbon Formation in southwestern Alabama.However, the stratified, fine-grained, well-sorted sand of the Bennock Millpond is lithologically very similar to the Perry Sand of the Fort Valley Group<Huddlestun and Hetrick, 1991)in central and southwestern Georgia.The upper, outcropping part of the Lisbon Formation (=Cubitostrea sellae{ormis Zone)in Burke County is divided into two formal members in this report: the Blue Bluff Member and the McBean Limestone Member.An undifferentiated Lisbon sand (Figure 5)is also associated with the McBean and Blue Bluff Members in northern Burke County.Type Locality The type locality of the Claiborne Group is the section of Lisbon Formation and Gosport Sand exposed at Claiborne Bluff on the Alabama River in Monroe County, Alabama.
Lithology The lithology of the Claiborne Group as a whole is dominated by quartz sand, clay and, to a lesser degree, calcite and biogenic debris.
Locally, or in some beds or stratigraphic subdivisions, any of the primary three lithic components may be minor or, rarely, absent. Subordinate lithic components include chert "buhrstone" (or cristobolitic claystone), glauconite, greensand, phosphate (both in the forms of vertebrate bone debris and black to brown, pelletal apatite), mica, pyrite, lignitic and carbonaceous material, zeolites, and shells and other bioclastic debris. Stratigraphic Relationehips The Claiborne Group in Georgia extends across the state from the Chattahoochee River to the Savannah River and into western South Carolina.
In Georgia east of the Ocmulgee River, the Congaree Formation appears to pinch out in the shallow subsurface. The stratigraphic relationship of the Congaree Formation with the Fort Valley Group and Oconee Group are unknown. The northern limit of the lower Lisbon Formation (Cubitostrea lisbonensis Zone) is in the subsurface from central or amtern Alabama to the western edge of the Savannah River where the formation crops out near McBean Creek. Stratigraphic relationships between the lower Lisbon-equivalent Still Branch Sand, and the Fort Valley and Oconee Groups are unknown. The location of the northern limit of the upper Lisbon Formation in eastern Georgia is probably defined by a coastward facies change into the kaolin-bearing "Jeffersonville" member of the Huber Formation (Oconee Group) of Huddlestun and Hetrick (1991). This stratigraphic relationship appears to hold as far east as the Savannah River area in Georgia. In Burke County, Georgia, the Claiborne Group disconformably overlies the Snapp Formation and is overlain by the Barnwell Group. The lithology of the Claiborne Group Mers from that of the underlying Wilcox Group in western Georgia in being typically less argillaceous and more calcareous and fo8siliferous.
In addition, the Wilcox Group sediments appear to be more abundantly and coarsely micaceous.
The lithology of the Claiborne Group Mers from that of the overlying Ocala Group (where the two groups are in contact) in being more sandy, argillaceous, glauconitic, less calcareous, and finer textured.
In eastern Georgia, it differs from the overlying Barnwell Group in being more calcareous with less separation of sand, calcite, and clay "marl".
In general, the depositional environment of the Claiborne Group was open marine, inner to middle neritic, relatively fine-grained, siliciclastic-dominated, continental shelf. Coastal marine deposits, outer shelf deposits, and carbonate bank deposits are not present in the Claiborne Group.
The Claiborne Group is mostly Middle Eocene, Lutetian and Bartonian in age in Georgia. The oldest formation of the group in Georgia, the Congaree Formation, is interpreted to be contained in planktonic foraminiferal Zone P 10 or P 11 (Hantkenina amgonensis Zone or Globigerinatheka subconglobata Zone). Gibson and Bybell (1983) reported Early Eocene ages for the lower part of the Tallahatta in Mississippi, Alabama, and Georgia. However, the senior author has identi6ied no Early Eocene planktonic foraminifera indicating the presence of planktonic foraminiferal zones P7, P8, or P9 in Georgia or Alabama. In western South Carolina, the upper Lower Eocene (Edwards, personal communication, 1993)
Fourmile Creek Formation of Fallaw and Price (1992,1995) is of Congaree Formation lithology and considered here to be lithostratigraphically a part of that formation. Although we cannot confirm a late Early Eocene age for the Congaree and Tallahatta Formations, based on the identifications of Edwards (personal communication, 1995) we can assign a late Early Eocene age for the lower part of the Claiborne Group in Georgia. The age range of the Claiborne Group in Georgia, therefore, is late Early Eocene through the Middle Eocene. This will be discussed more fully in the section on the age of the Congaree Formation. The youngest Lithology The lithology of the Claiborne Group as a whole is dominated by quartz sand, clay and, to a lesser degree, calcite and biogenic debris.Locally, or in some beds or stratigraphic subdivisions, any of the primary three lithic components may be minor or, rarely, absent.Subordinatelithiccomponents include chert"buhrstone" (or cristobolitic claystone), glauconite, greensand, phosphate (both in the forms of vertebrate bone debris and black to brown, pelletal apatite), mica, pyrite, lignitic and carbonaceous material, zeolites, and shells and other bioclastic debris.Stratigraphic Relationships The Claiborne Group in Georgia extends across the state from the Chattahoochee River to the Savannah River and into western South Carolina.In Georgia east of the Ocmulgee River, the Congaree Formation appears to pinch out in the shallow subsurface.
The stratigraphic relationship of the Congaree Formation with the Fort Valley Group and Oconee Group are unknown.The northern limit of the lower Lisbon Formation (Cubitostrea lisbonensis Zone)is in the subsurface from central or eastern Alabama to the western edge of the Savannah River where the formation crops out near McBean Creek.Stratigraphic relationships between the lower Lisbon-equivalent Still Branch Sand, and the Fort Valley and Oconee Groups are unknown.The location of the northern limit of the upper Lisbon Formation in eastern Georgia is probably defined by a coastward facies change into the kaolin-bearing"Jeffersonville" member of the Huber Formation (Oconee Group)of Huddlestun and Hetrick (1991).This stratigraphic relationship appears to hold as far east as the Savannah River area in Georgia.In Burke County, Georgia, the Claiborne Group disconformably overlies the Snapp Formation and is overlain by the Barnwell Group.The lithology of the Claiborne Group differs from that of the underlying Wilcox Group in western Georgia in being typically less argillaceous and more calcareous and 32 foSsiliferous.
In addition, the Wilcox Group sediments appear to be more abundantly and coarsely micaceous.
The lithology of the Claiborne Group differs from that of the overlying Ocala Group (where the two groups are in contact)in being more sandy, argillaceous, glauconitic, less calcareous, and finer textured.In eastern Georgia, it differs from the overlying Barnwell Group in being more calcareous with less separation of sand, calcite, and clay"marl".In general, the depositional environment of the Claiborne Group was open marine, inner to middle neritic, relatively fine-grained, siliciclastic-dominated, continental shelf.Coastal marine deposits, outer shelf deposits, and carbonate bank deposits are not present in the Claiborne Group.Age The Claiborne Group is mostly Middle Eocene, Lutetian and Bartonian in age in Georgia.The oldest formation of the group in Georgia, the Congaree Formation, is interpreted to be contained in planktonic foraminiferal Zone P 10 or P 11 (JIantkenina aragonensis Zone or Globigerinatheka subconglobata Zone).Gibson and Bybell (1983)reported Early Eocene ages for the lower part of the Tallahatta in Mississippi, Alabama, and Georgia.However, the senior author has identified no Early Eocene planktonic foraminifera indicating the presence of planktonic foraminiferal zones P7, P8, or P9 in Georgia or Alabama.In western South Carolina, the upper Lower Eocene (Edwards, personal communication, 1993)Fourmile Creek Formation of Fallaw and Price (1992, 1995)is of Congaree Formation lithology and considered here to be lithostratigraphically a part of that formation.
Although we cannot confirm a late Early Eocene age for the Congaree and Tallahatta Formations, based on the identifications of Edwards (personal communication, 1995)we can assign a late Early Eocene age for the lower part of the Claiborne Group in Georgia.The age range of the Claiborne Group in Georgia, therefore, is late Early Eocene through the Middle Eocene.This will be discussed more fully in the section on the age of the Congaree Formation.
The youngest confirmable Claiborne Group in Georgia, the upper part of the Lisbon Formation (Cubitostrea sellaefonnis Zone) is interpreted to be in the planktonic foraminiferal zone P 13 (Ohulimides beckmcznni Zone). Unless the Clinchfield Sand is temporally equivalent to the Gosport (Huddlestun and Hetrick, 1986), no post-Lisbon, Claibornian sediments are currently recognized in Georgia. In that case, it is possible that the upper Claibornian Gosport Sand of the eastern Gulf Coast stratigraphically correlates with the Clinchfield Formation of Barnwell Group, which is lower Jacksonian.
According to established usage (Huddlestun and Hetrick, 1986), the Clinchfield may be Late Eocene in age but Claibornian in stage. Congaree Formation Definition As applied here, the Congaree Formation in South Carolina and Georgia consists of an updip, variably siliceous clay, and clay and sand lithofacies, and a downdip, shallow subsurface, massive-bedded, fine- to medium-grained, moderately to well-sorted, soft and barely coherent sand Zithofacies.
The Congaree Formation of this report differs from the Congaree Formation of SRS in South Carolina (Fallaw and Price, 1992, 1995) in that the Fourmile Branch Formation of Fallaw and Price (1992,1995), lithostratigraphically is included in the Congaree Formation, in Burke County. A further discussion of the Congaree nomenclatural history is included in Appendix 3. Based on literature from the outcropping, type area of the Congaree Formation (Sloan, 1907, 1908; Cooke, 1936; Cooke and MacNeil 19521, the type Congaree consists primarily of shale and clay with subordinate amounts of quartz sand occurring either in beds or interstitially.
According to Paul Nystrom (personal communication, 1995) of the South Carolina Geological Survey, however, there is more sand in the Congaree Formation in its type area than has been reported in the literature.
If the type Congaree were consistently a clay and shale in its type area, as indicated in early reports, it would not be litho- stratigraphically proper to extend the name Congaree to shallow subsurface sand sections in SRS in South Carolina or in Georgia. However, we believe the discrepancy between the reported outcropping Congaree shale and clay lithology in its type area, and that in the shallow subsurface, is a result of relative ease of erosion and mass wasting of the soft sand lithofacies in outcrop. This leaves a relatively high proportion of the argillaceous lithofacies exposed. As a result, we propose to formally expand (redefine) the name Congaree to include the shallow subsurface sand sections in South Carolina and across Georgia westward to the Chattahoochee River. In the northern, updip part of Burke County, the Congaree Formation is more lithologically variable than it is in southern Burke County and consists of sand and clay. In southern Burke County, the Congaree Formation is homogeneous and consists of sand. The Congaree sand extends across the subsurface of Georgia to the Chattahoochee River area. In the past the lower Claibornian section in Georgia and in the vicinity of the Chattahoochee River has been called Tallahatta Formation (MacNeil, 1944% 1944b; Herrick, 1961; Toulmin and LaMoreaux, 1963; Owen, 1963; Mansalis and Friddell, 1975; Reinhardt and Gibson, 1981; McFadden, et al, 1986). In its type area, the Tallahatta Formation is a lightweight, siliceous claystone (buhrstone), and quartz sand, if present, is a minor lithic component.
The Tallahatta is very resistant to erosion and, therefore, forms a cuesta where the formation is present Typical Tallahatta Formation lithology is present only as lenses in an updip, predominantly argillaceous sand formation east of southwestern Alabama and in the type area of the Congaree. The Tallahatta Formation exists neither in the lower Claibornian stratigraphic position in the Chattahoochee River area, nor in the shallow subsurface of Georgia east of the Chattahoochee.
The lower Claibornian of the Chattahoochee River area contains exposures that cannot be distinguished from the Congaree Formation in its type area. Therefore, we recommend the adoption of the name Congaree for the lower confirmable Claiborne Group in Georgia, the upper part of the Lisbon Formation (CubitostTea sellaeformis Zone)is interpreted to be in the planktonic foraminiferal zone P 13 (Orbulinoides beckmanni Zone).Unless the Clinchfield Sand is temporally equivalent to the Gosport (Huddlestun and Hetrick, 1986), no post-Lisbon, Claibornian sediments are currently recognized in Georgia.In that case, it is possible that the upper Claibornian Gosport Sand of the eastern Gulf Coast stratigraphically correlates with the Clinchfield Formation of Barnwell Group, which is lower Jacksonian.
According to established usage (Huddlestun and Hetrick, 1986), the Clinchfield may be Late Eocene in age but Claibornian in stage.Congaree Formation Definition As applied here, the Congaree Formation in South Carolina and Georgia consists of an updip, variably siliceous clay, and clay and sand lithofacies, and a downdip, shallow subsurface, massive-bedded, fine-to medium-grained, moderately to well-sorted, soft and barely coherent sand lithofacies.
The Congaree Formation of this report differs from the Congaree Formation of SRS in South Carolina (Fallaw and Price, 1992, 1995)in that the Fourmile Branch Formation of Fallaw and Price (1992,1995), lithostratigraphically is included in the Congaree Formation, in Burke County.A further discussion of the Congaree nomenclatural history is included in Appendix 3.Based on literature from the outcropping, type area of the Congaree Formation (Sloan, 1907, 1908;Cooke, 1936;Cooke and MacNeil 1952), the type Congaree consists primarily of shale and clay with subordinate amounts of quartz sand occurring either in beds or interstitially.
According to Paul Nystrom (personal communication, 1995)of the South Carolina Geological Survey, however, there is more sand in the Congaree Formation in its type area than has been reported in the literature.
If the type Congaree were consistently a clay and shale in its type area, as indicated in 33 early reports, it would not bestratigraphically proper to extend the name Congaree to shallow subsurface sand sections in SRS in South Carolina or in Georgia.However, we believe the discrepancy between the reported outcropping Congaree shale and clay lithology in its type area, and that in the shallow subsurface, is a result of relative ease of erosion and mass wasting of the soft sand lithofacies in outcrop.This leaves a relatively high proportion of the argill.aceous lithofacies exposed.As a result, we propose to formally expand (redefine) the name Congaree to include the shallow subsurface sand sections in South Carolina and across Georgia westward to the Chattahoochee River.In the northern, updip part of Burke County, the Congaree Formation is more lithologically variable than it is in southern Burke County and consists of sand and clay.In southern Burke County, the Congaree Formation is homogeneous and consists of sand.The Congaree sand extends across the subsurface of Georgia to the Chattahoochee River area.In the past the lower Claibornian section in Georgia and in the vicinity of the Chattahoochee River has been called Tallahatta Formation (MacNeil, 1944a., 1944b;Herrick, 1961;Toulmin and LaMoreaux, 1963;Owen, 1963;Marsalis and Friddell, 1975;Reinhardt and Gibson, 1981;McFadden, et aI, 1986).In its type area, the Tallahatta Formation is a lightweight, siliceous claystone (buhrstone), and quartz sand, if present, is a minor lithic component.
The Tallahatta is very resistant to erosion and, therefore, forms a cuesta where the formation is present.Typical Tallahatta Formation lithology is present only as lenses in an updip, predominantly argillaceous sand formation east of southwestern Alabama and in the type area of the Congaree.The Tallahatta Formation exists neither in the lower Claibornian stratigraphic position in the Chattahoochee River area, nor in the shallow subsurface of Georgia east of the Chattahoochee.
The lower Claibornian of the Chattahoochee River area contains exposures that cannot be distinguished from the Congaree Formation in its type area.Therefore, we recommend the adoption of the name Congaree for the lower Claibornian westward across the state of Georgia to the Chattahoochee River. The Congaree Formation is placed in the Claiborne Group in this report because exposures of the formation in east central Alabama-and the Chattahoochee River area have always been considered an integral part of the Claiborne Group.
'Qpe Locality Sloan (1907, 1908) did not designate a type locality for the Congaree Formation and, therefore, there is no type locality by original designation for the formation. However, Cooke (1936, p. 59) assigned the amphitheater at the head of First Creek as the principal reference locality Qectostratotype) for the formation.
The exposure of the Congaree in the amphitheater is the principal reference section aectostratotype) for the Congaree Formation.
The principal reference locality is in Lexington County, 0.8 mile (1.28 km) west of Gaston in the updip central Coastal Plain of South Carolina.
In eastern Burke County, five cores are designated as Congaree Formation reference localities in Georgia (Table 7). The core site localities are described in Appendix 1, and the coordinates are listed in Table 1. Core TR92-1 has good recovery of the formation (66%)
and is representative of the updip, mixed sand and clay lithofacies of the Congaree in northern Burke County. Core TR92-2 contains a representation of the bioturbated and burrowed lithofacies.
The TR92-4 core contains siliceous clay as the dominant lithic component.
This lithofacies is similar to the typical outcropping Congaree in the type area in central South Carolina.
Core TR92-5 contains some of the ranges of lithology seen in the Congaree in northern Burke County. Core VG-6 is characteristic of the downdip, massive-bedded, barely coherent, fine-grained, well-sorted sand lithofacies in Burke County and of the shallow subsurface in Georgia westward to the Chattahoochee River area.
The core recovery of the Congaree Formation (93%)
in core VG-6 is unusually good for the formation.
Other useful reference sections of the Congaree Formation in Georgia include three Bxposures in the area covered on the 1:24,000 Columbia NE Ah.-Ga. quadrangle map, and four cores from sites in southwestern and central Georgia. The three exposures in the Columbia 1:24,000 quadrangle are hypostratotypes and are located: 1.) in Factory Creek, at and downstream from the County Road 140 bridge over the creek, two miles (3.2 km) from the northern-most measured section of the Tallahatta Formation of Toulmin and LaMoreaux (1963). This is stop 8, second day of the Georgia Geological Society field trip (Marsalis and Friddell, 1975);
2.) exposures of the formation along Red Branch, a small tributary of the Chattahoochee River, three miles (4.8 km) north of Factory Creek; and 3.) the exposure of the Congaree on Odum Creek, less than 0.25 mile (0.4 km) from the public boat ramp at the confluence of Odum Creek with the Chattahoochee River (near Mile 56 on the Chattahoochee River).
The Congaree exposed at the waterfall on Odum Creek exposure contains a calcareous and fossiliferous bed, with the oyster Cubitostrea perplicata and may represent Bed 28 of Toulmin and LaMoreaux (1963). The other core sites (hypostratotypes), not located in Burke County (Table 8), are listed to illustrate lithofacies variations of the Congaree Formation across central and southwestern Georgia. In the USGS Albany core (GGS-3187), the Congaree Formation occurs in the interval from 401 feet to 539 feet. It is representative of the massive-bedded, poorly coherent to incoherent, sand lithofacies.
The upper part of the Congaree, from 401 feet to 478 feet, is characteristically devoid of calcite (except for widely scattered thin sandy limestone beds), and consists of variably coherent to incoherent, massive-bedded, sparsely and sporadically glauconitic, variably and slightly argillaceous sand with scattered clay laminae and variable bioturbation.
From 478 feet to the top of the Bashi Member of the Hatchetigbee Formation at approximately 539 feet, the Congaree Formation consists of glauconitic, calcareous, microfossiliferous, argillaceous, fine sand. The Congaree Formation is overlain with apparent gradation by the lower Lisbon Formation Claibornian westward across the state of Georgia to the Chattahoochee River.The Congaree Formation is placed in the Claiborne Group in this report because exposures of the formation in east central Alabama-and the Chattahoochee River area have always been considered an integral part of the Claiborne Group.Type Locality Sloan (1907, 1908)did not designate a type locality for the Congaree Formation and, therefore, there is no type locality by original designation for the formation.
However, Cooke (1936, p.59)assigned the amphitheater at the head of First Creek as the principal reference locality Oectostratotype) for the formation.
The exposure of the Congaree in the amphitheater is the principal reference section Oectostratotype) for the Congaree Formation.
The principal reference locality is in Lexington County, 0.8 mile (1.28 km)west of Gaston in the updip central Coastal Plain of South Carolina.In eastern Burke County, five cores are designated as Congaree Formation reference localities in Georgia (Table 7).The core site localities are described in Appendix 1, and the coordinates are listed in Table 1.Core TR92-1 has good recovery of the formation (66%)and is representative of the updip, mixed sand and clay lithofacies of the Congaree in northern Burke County.Core TR92-2 contains a representation of the bioturbated and burrowed lithofacies.
The TR92-4 core contains siliceous clay as the dominant lithic component.
This lithofacies is similar to the typical outcropping Congaree in the type area in central South Carolina.Core TR92-5 contains some of the ranges of lithology seen in the Congaree in northern Burke County.Core VG-6 is characteristic of the downdip, massive-bedded, barely coherent, fine-grained, well-sorted sand lithofacies in Burke County and of the shallow subsurface in Georgia westward to the Chattahoochee River area.The core recovery of the Congaree Formation (93%)in core VG-6 is unusually good for the formation.
Other useful reference sections of the Congaree Formation in Georgia include three 34 exposures in the area covered on the 1:24,000 Columbia NE Ala.-Ga.quadrangle map, and four cores from sites in southwestern and central Georgia.The three exposures in the Columbia 1:24,000 quadrangle are hypostratotypes and are located: 1.)in Factory Creek, at and downstream from the County Road 140 bridge over the creek, two miles (3.2 km)from the northern-most measured section of the Tallahatta Formation of Toulmin and LaMoreaux (1963).This is stop 8, second day of the Georgia Geological Society field trip (Marsalis and Friddell, 1975);2.)exposures of the formation along Red Branch, a small tributary of the Chattahoochee River, three miles (4.8 km)north of Factory Creek;and 3.)the exposure of the Congaree on Odum Creek, less than 0.25 mile (0.4 km)from the public boat ramp at the confluence of Odum Creek with the Chattahoochee River (near Mile 56 on the Chattahoochee River).The Congaree exposed at the waterfall on Odum Creek exposure contains a calcareous and fossiliferous bed, with the oyster Cubitostrea perplicata and may represent Bed 28 of Toulmin and LaMoreaux (1963).The other core sites (hypostratotypes), not located in Burke County (Table 8), are listed to illustrate lithofacies variations of the Congaree Formation across central and southwestern Georgia.In the USGS Albany core (GGS-3187), the Congaree Formation occurs in the interval from 401 feet to 539 feet.It is representative of the massive-bedded, poorly coherent to incoherent, sand lithofacies.
The upper part of the Congaree, from 401 feet to 478 feet, is characteristically devoid of calcite (except for widely scattered thin sandy limestone beds), and consists of variably coherent to incoherent, massive-bedded, sparsely and sporadically glauconitic, variably and slightly argillaceous sand with scattered clay laminae and variable bioturbation.
From 478 feet to the top of the Bashi Member of the Hatchetigbee Formation at approximately 539 feet, the Congaree Formation consists of gla uconitic, calcareous, microfossiliferous, argillaceous, fine sand.The Congaree Formation is overlain with apparent gradation by the lower Lisbon Formation Congaree Formation reference sections in eastern Burke County. I, 11 COW SI* ( GGS core number I She Untion a- 1 Top of formation-I Bottom of see Flgure 2 Table 1 (Cubitostrea lisbonensis Zone?) and is underlain communication, 1995) indicate an early Middle VG-6 with apparent gradation (paraconformity?)
by the Bashi Member of the Hatchetigbee Formation.
In the GGS Sumter 9A core from eastern Sumter County, the Congaree Formation is characteristically a poorly coherent, fine- to medium-grained sand that is difficult to recover in coring operations
(-28 % recovery).
The sand is characteristically noncalcareous, massive- bedded and structureless with rare scattered beds of laminated clay. The GGS Laurens County core contains the only Congaree Formation that has been identified in the Ocmulgee River area. The sand lithology is typical soft, incoherent (14% recovery), he- to medium-grained and well- sorted, with scattered, thin carbonaceous or lignitic beds. There is a bed (9 feet thick) of hard, silty kaolin at the top of the formation. Dinoflagellate identifications by Edwards (personal communication, 1995) indicate a late Early Eocene to early Middle Eocene age for the formation in this core. The GGS Pula& 5 core contains the only section of Congaree Formation that has been identified from the vicinity of the Oconee River in the central Georgia Coastal Plain. The sand lithology is typical for the formation (fine- to coarse-grained and well- sorted). However, there are beds (< 8 feet [2 ml thick) of argillaceous, carbonaceous sand scattered throughout the formation as thin beds to laminae of clay and carbonaceous clay. There is also a 10 foot thick, massive-bedded, greenish gray kaolin at the top of the formation. Dinoflagellates identified by Edwards (persod Mean Sea Level (-1 Eocene age for the Congaree Formation. "n/a9-Not applicable n/a Lithology feet below surface In northern Burke County, the lithology of the Congaree Formation is variable, with more beds of clay ("cristobolitic" claystone in the core TR92-4), interstitial clay, some scattered clay clasts(?), and bioturbation. This lithofacies is similar to the Congaree Formation in its type area. In the southern part of the county the sand is almost barren of interstitial clay and is lithologically the same as that in the subsurface in central and western Georgia. In general, in Burke County, there is more clay and silica in updip (nearshore)
Congaree Formation, and relatively clean sand with minor clay and silica in downdip (seaward) sections. Subordinate lithic components of the Congaree Formation in Burke County include mica, sporadic occurrences and low concentrations of pelletal phosphate (sandy phosphate pebbles occur rarely at the base of the formation), scattered thin beds of siliceous sandstone, variable occurrences of dark minerals, variable but minor amounts of lignitic fragments, lignitic flecks, and carbonaceous streaks (mo&ly in updip, northern Burke County), rare to common acicular gypsum-bloom on cores (as opposed to "cauliflawei"-shaped gypsum-bloom), some sulphur bloom?, and minor pyrite. A thin bed of fossiliferous, glauconitic, very calcareous sandstone to very sandy limestone occurs at the base of the formation in southernmost. Burke County (core formation-feet below surface 217 328 428 Table 7 Congaree Formation reference sections In eastern Burke County.nla-Not applicable Core Site GGS core number Site ElevaUon above Top of formaUon-Bottom of see Figure 2 Mean Sea Level feet below surface formaUon-feet Table 1 (feet)below surface TR92-1 GG8-3674 235 245 270 TR92-2 GG8-3762 285 308 330 TR92-4 GG8-3782 192 182.5 213 TR92-5 GG8-3792 235 272 290 VG-6 nla 217 328 428..(Cubitostrea lisbonensis Zone?)and is underlain with apparent gradation (paraconformity?)
by the Bashi Member of the Hatchetigbee Formation.
In the GGS Sumter 9A core from eastern Sumter County, the Congaree Formation is characteristically a poorly coherent, tine-to medium-grained sand that is difficult to recover in coring operations
(-28%recovery).
The sand is characteristically noncalcareous,bedded and structureless with rare scattered beds of laminated clay.The GGS Laurens County core contains the only Congaree Formation that has been identified in the Ocmulgee River area.The sand lithology is typical soft, incoherent (14%recovery), tine-to medium-grained andsorted, with scattered, thin carbonaceous or lignitic beds.There is a bed (9 feet thick)of hard, silty kaolin at the top of the formation.
Dinoflagellate identifications by Edwards (personal communication, 1995)indicate a late Early Eocene to early Middle Eocene age for the formation in this core.The GGS Pulaski 5 core contains the only section of Congaree Formation that has been identified from the vicinity of the Oconee River in the central Georgia Coastal Plain.The sand lithology is typical for the formation (tine-to coarse-grained andsorted).However, there are beds<<8 feet[2 m]thick)of argillaceous, carbonaceous sand scattered throughout the formation as thin beds to laminae of clay and carbonaceous clay.There is also a 10 foot thick, massive-bedded, greenish gray kaolin at the top of the formation.
Dinoflagellates identified by Edwards (personal communication, 1995)indicate an early Middle Eocene age for the Congaree Formation.
Lithology In northern Burke County, the lithology of the Congaree Formation is variable, with more beds of clay ("cristobolitic" claystone in the core TR92-4), interstitial clay, some scattered clay clasts(?), and bioturbation.
This lithofacies is similar to the Congaree Formation in its type area.In the southern part of the county the sand is almost barren of interstitial clay and is lithologically the same as that in the subsurface in central and western Georgia.In general, in Burke County, there is more clay and silica in updip (nearshore)
Congaree Formation, and relatively clean sand with minor clay and silica in downdip (seaward)sections.Subordinate lithic components of the Congaree Formation in Burke County include mica, sporadic occurrences and low concentrations of pelletal phosphate (sandy phosphate pebbles occur rarely at the base of the formation), scattered thin beds of siliceous sandstone, variable occurrences of dark minerals, variable but minor amounts of lignitic fragments, flecks, and carbonaceous streaks (mostly in updip, northern Burke County), rare to common acicular gypsum-bloom on cores (as opposed to"cauliflower"-shaped gypsum-bloom), some sulphur bloom?, and minor pyrite.A thin bed of fossiliferous, glauconitic, very calcareous sandstone to very sandy limestone occurs at the base of the formation in southernmost Burke County (core 35 VG-8). Glauconite, limestone, calcite, and shells are especially characteristic of the formation in the more downdip outcrop in southwestern Georgia whereas traces of pelletal phosphate are more conspicuous in central and eastern Georgia. The Congaree typically is massive- bedded and devoid of primary sedimentary structures.
However, some intervals at some sites contain vaguely and crudely bedded to conspicuously bedded sands and some thinly layered to laminated lignitic clay beds. Bioturbation is common in some cores from northern Burke County; the sand and clay components are marbled in those cores. Only a few, thin, clearly stratified sand intervals have been observed in the Congaree.
The color of the Congaree sands includes shades of brown, orange, greenish grays, olive grays, olive black to brownish bla* and light grays. Smectitic clay beds from cores in the Congaree are commonly gypsiferous, noncalcareous, fissile and papery, waxy, and may be slightly sandy to silty. They are finely micaceous with some dark minerals found along partings.
There are some interbeds or interlaminae of fine to very fine grained sand. Interstitial clay commonly occurs in the Table 8 Congaree Formation reference sections In Georgia west of Burke County. bioturbated intervals. There is minor "cristobolitic" claystone and silica-cemented sandstone in Burke County. The claystone is siliceous, indurated, and shaley with very fine sand to silt and mica on bedding planes.
The claystone displays imgular to conchoidal fracture.
The colors of Congaree clays range from shades of olive grays, yellowish grays, greenish grays, brownish grays to light grays. Near the Chattahoochee River and in northern Burke County, the outcropping, updip Congaree is lithologically more variable than in the shallow subsurface across Georgia. This lithofacies is also more reminiscent of the Congaree in its type area. We interpret this pattern of lithology distributions as being consistent with the more varied coastal marine to shallow, inner neritic lithofacies versus the much less varied lithofacies of offshore depositional environments.
Because of the presence of partially indurated, resistant, siliceous sand or thin beds of siliceous sandstone or claystone in the western Georgia outcrop, waterfalls and rapids are common along small tributary creeks of the Chattahoochee River. Typical Congaree in southwestern Georgia is commonly glauconitic with scattered beds that are highly glauconitic ComSite.cn, Appendlx 1 USGS Albany GGS Sumter 9A GGS Pulaskl 5 USGS Laurens 1 GGS 0010 number GGS-3187 GGS3366 GGS-3511 GGS-3523 USGS quadrangle map/ LatttudaN
/Longltudaw
(.rt) Albany East 31' 31' 05' 84O 06' 44' Drayton 32O 04' w 83°ws West Lake 32O 22' !W 83O 29' 17- Dudley 32O 30' 59- 83O 02' 43' ElwaUon feetabve mwn led 1 95 270 355 285 Top of formallon-feet below rurhce 401 114 228 312.5 Bottom of fonnatlon-feet below rurface 539 1 88 380 421 Table 8 Congaree Formation reference sections In Georgia west of Burke County.Core SIte He GGS USGS qWldrqle E1evlltlon Top of Bottom of Appendix 1 cor.map/feel above formation-feel formation-feel number Latltude-N mean...below surface below surface/Longftude-W level (Mt.)USGS GGS-3187 Albany East 195 401 539 Albany 31°31'05" 84°06'44" GGS GGS-3366 Drayton 270 114 188 Sumter 9A 32°04'03" 83°59'23" GGS GG8-3511 West Lake 355 228 380 Pulaski 5 32°22'50"83°29'17" USGS GGS-3523 Dudley 285 312.5 421 Laurens 1 32°30'59" 83°02'43" VG-B).Glauconite, limestone, calcite, and shells are especially characteristic of the formation in the more downdip outcrop in southwestern Georgia whereas traces of pelletal phosphate are more conspicuous in central and eastern Georgia.The Congaree typically isbedded and devoid of primary sedimentary structures.
However, some intervals at some sites contain vaguely and crudely bedded to conspicuously bedded sands and some thinly layered to laminated lignitic clay beds.Bioturbation is common in some cores from northern Burke County;the sand and clay components are marbled in those cores.Only a few, thin, clearly stratified sand intervals have been observed in the Congaree.The color of the Congaree sands includes shades of brown, orange, greenish grays, olive grays, olive black to brownish black, and light grays.Smectitic clay beds from cores in the Congaree are commonly gypsiferous, noncalcareous, fissile and papery, waxy, and may be slightly sandy to silty.They are finely micaceous with some dark minerals found along partings.There are some interbeds or interlaminae of fine to very fine grained sand.Interstitial clay commonly occurs in the 36 bioturbated intervals.
There is minor"cristobolitic" claystone and silica-cemented sandstone in Burke County.The claystone is siliceous, indurated, and shaley with very fine sand to silt and mica on bedding planes.The claystone displays irregular to conchoidal fracture.The colors of Congaree clays range from shades of olive grays, yellowish grays, greenish grays, brownish grays to light grays.Near the Chattahoochee River and in northern Burke County, the outcropping, updip Congaree is lithologically more variable than in the shallow subsurface across Georgia.This lithofacies is also more reminiscent of the Congaree in its type area.We interpret this pattern of lithology distributions as being consistent with the more varied coastal marine to shallow, inner neritic lithofacies versus the much less varied lithofacies of offshore depositional environments.
Because of the presence of partially indurated, resistant, siliceous sand or thin beds of siliceous sandstone or claystone in the western Georgia outcrop, waterfalls and rapids are common along small tributary creeks of the Chattahoochee River.Typical Congaree in southwestern Georgia is commonly glauconitic with scattered beds that are highly glauconitic (Toulmin and LaMoreaux, 1963). Phosphate is not apparent on casual inspection of the outcropping formation, but Herrick (1961) reported "phosphate" in this formation from cuttings from most wells between the Chattahoochee and Flint Rivers, and from sands we interpret to be Congaree Formation east of the Flint River. Silica-replaced shells are locally present and blocks or pods of fossiliferous chert or chert-cemented sandstone are locally conspicuous (Marsalis and Friddell, 1975), indicating that the formation was originally calcareous in the outcrop area. In the downdip outcrop area in southwestern Georgia, the Congaree Formation is less variable than in the updip outcrop area and consists of thick, massive-bedded, noncalcareous to calcareous sand.
Locally, scattered beds of calcareous sandstone or sandy limestone are present. Similarly in this area, the formation is more fossilifem with locally abundant Cubitostrea perplicata.
There are no known lithologically varied, near shore lithofacies of the Congaree between the drainage basins of the Chattahoochee and Savannah Rivers. The characteristic, widespread sand lithofacies of the Congaree occurs in the shallow subsurface and extends westward across Georgia from the Savannah River area to the Chattahoochee River area. Congaree sands are typically soft, barely coherent to incoherent, massively bedded and structureless.
Sand size ranges from fine- to coarse-grained with rare occurrences of very coarse sand, granules and pea gravel. Normally the sand is fine- to medium grained and well- sorted. Sand sorting is variable and ranges from well- to poorly sorted. Most commonly the sand is fine- to medium-grained and well- to moderately well sorted. Some coarser quartz sand grains are conspicuously rounded. Core recovery in the sand is characteristically poor. The Congaree Formation is very permeable and constitutes the "Claiborne" part of the Clayton-Claiborne aquifer in southwestern Georgia and the Gordon aquifer in eastern Burke County. In this predominantly thick sand lithofacies, the Congaree is noncalcareous, nonglauconitic, nonphosphatic (see Herrick, 1981), nonsiliceous and ve j slightly argillaceous. Some scattered thin clay beds are commonly carbonaceous or lignitic to some degree. Lignitic material is most conspicuous in the updip areas and diminishes downdip. In the Pulaski County and Laurens County cores, a bed of hard, chunky and blocky fractured, Middle Eocene-type kaolin occurs at the top of the Congaree Formation.
Stratigraphic Relationships In the central Coastal Plain of Georgia, from northern Burke County, southwestward through central Laurens County, through Pulaski County, through Lee County and into Randolph County, the Congaree appears to pinch out northward (updip) in the subsurface.
Further westward, the Congaree grades laterally into the Tallahatta Formation in central and western Alabama. In northern Burke County, Georgia, the Congaree Formation disconformably overlies the Snapp Formation and is gradationally (or paraconformably) overlain by the Bennock Millpond Sand Member of the Still Branch Sand. In southern Burke County, it is overlain conformably or paraconformably by the Still Branch Sand. In western Georgia, the Congaree Formation disconformably, or paraconformably, overlies the Bashi Member of the Hatchetigbee Formation, and is overlain by the Lisbon Formation. Elsewhere in the state, the Congaree disconformably overlies the Tuscahoma Formation and undifferentiated Wilcox or Midway Groups. It is disconformably overlain by the Lisbon Formation (Cubitostrea sellaeformis Zone) in outcrop in western and central Georgia but appem to be conformable with the Cubitostrea lisbonensis Zone of the lower Lisbon Formation in the subsurface of Georgia. Throughout the subcrop area in Georgia, the Congaree Formation thickens rapidly downdip, increasing from 0 to over 100 feet thick within a few miles.
In the Savannah River area, however, the rate of seaward thickening is much less, approximately 2.3 feet per mile. The thickest known section of the Congaree Formation is 192 feet (59 m) near Albany, (Toulmin and LaMoreaux, 1963).Phosphate is not apparent on casual inspection of the outcropping formation, but Herrick (1961)reported"phosphate" in this formation from cuttings from most wells between the Chattahoochee and Flint Rivers, and from sands we interpret to be Congaree Formation east of the Flint River.Silica-replaced shells are locally present and blocks or pods of fossiliferous chert or chert-cemented sandstone are locally conspicuous (Marsalis and Friddell, 1975), indicating that the formation was originally calcareous in the outcrop area.In the downdip outcrop area in southwestern Georgia, the Congaree Formation is less variable than in the updip outcrop area and consists of thick, massive-bedded, noncalcareous to calcareous sand.Locally, scattered beds of calcareous sandstone or sandy limestone are present.Similarly in this area, the formation is more fossiliferous with locally abundant Cubitostrea perplicata.
There are no known lithologically varied, near shore lithofacies of the Congaree between the drainage basins of the Chattahoochee and Savannah Rivers.The characteristic, widespread sand lithofacies of the Congaree occurs in the shallow subsurface and extends westward across Georgia from the Savannah River area to the Chattahoochee River area.Congaree sands are typically soft, barely coherent to incoherent, massively bedded and structureless.
Sand sizerangesfrom fine-to coarse-grained with rare occurrences of very coarse sand, granules and pea gravel.Normally the sand is fine-to medium grained andsorted.Sand sorting is variable and ranges from well-to poorly sorted.Most commonly the sand is fine-to medium-grained and well-to moderately well sorted.Some coarser quartz sand grains are conspicuously rounded.Core recovery in the sand is characteristically poor.The Congaree Formation is very permeable and constitutes the"Claiborne" part of the Clayton-Claiborne aquifer in southwestern Georgia and the Gordon aquifer in eastern Burke County.In this predominantly thick sand lithofacies, the Congaree is noncalcareous, nonglauconitic, nonphosphatic (see Herrick, 1961), nonsiliceous and very 37 slightly argillaceous.
Some scattered thin clay beds are commonly carbonaceous or lignitic to some degree.Lignitic material is most conspicuous in the updip areas and diminishes downdip.In the Pulaski County and Laurens County cores, a bed of hard, chunky and blocky fractured, Middle Eocene-type kaolin occurs at the top of the Congaree Formation.
Stratigraphic Relationships In the central Coastal Plain of Georgia, from northern Burke County, southwestward through central Laurens County, through Pulaski County, through Lee County and into Randolph County, the Congaree appears to pinch out northward (updip)in the subsurface.
Further westward, the Congaree grades laterally into the Tallahatta Formation in central and western Alabama.In northern Burke County, Georgia, the Congaree Formation disconformably overlies the Snapp Formation and is gradationally (or paraconformably) overlain by the Bennock Millpond Sand Member of the Still Branch Sand.In southern Burke County, it is overlain conformably or paraconformably by the Still Branch Sand.In western Georgia, the Congaree Formation disconformably, or paraconformably, overlies the Bashi Member of the Hatchetigbee Formation, and is overlain by the Lisbon Formation.
Elsewhere in the state, the Congaree disconformably overlies the Tuscahoma Formation and undifferentiated Wilcox or Midway Groups.It is disconformably overlain by the Lisbon Formation (Cubitostrea sellaeformis Zone)in outcrop in western and central Georgia but appears to be conformable with the Cubitostrea lisbonensis Zone of the lower Lisbon Formation in the subsurface of Georgia.Throughout the subcrop area in Georgia, the Congaree Formation thickens rapidly downdip, increasing from 0 to over 100 feet thick within a few miles.In the Savannah River area, however, the rate of seaward thickening is much less, approximately 2.3 feet per mile.The thickest known section of the Congaree Formation is 192 feet (59 m)near Albany, Georgia, in the USGS Albany core. The known average thickness of the Congaree Formation in central and southwestern Georgia is 124 feet. In eastern Burke County, the thickness of the Congaree Formation ranges from 0 feet in the north to 62 feet (10 m) in the south (Figure 13). The average thickness of the Congaree in eastern Burke County is 38 feet (12 m). However, in the study area in northern Burke County, the Congaree Formation ranges in thickness from 0 feet in the GGS McBean core to 42 feet in core TR92-3. The average thickness of the formation is 21 feet (6.4 m). In the vicinity of the projected location of the Pen Branch fault, the Congaree Formation thins to less than 20 feet (Figure 13). From northern Burke County to the Screven County line, average dip on the top of the Congaree Formation is approximately 12 feet per mile to the southeast (Figure 14). From the vicinity of McBean Creek to the vicinity of the Pen Branch fault, average dip is approximately 14 feet per mile. Southeast of the Pen Branch fault, there is a dip reversal (Figure 14), which is followed by a return to a dip of 14 feet per mile to the county line.
The Congaree Formation is distinguished from the underlying Snapp Formation by the presence of gray sand and thinly bedded to laminated clay in contrast to the top of the Snapp Formation which consists of "bleached", pyritic, very light gray to white kaolin. Deeper in the Snapp Formation, the kaolin is mottled with various shade of red, reddish brown, orange, and gray. The underlying sand is characteristically white, kaolinitic, variably micaceous, poorly sorted and medium- to coarse-grained.
In northern Burke County, the Congaree is distinguished from the overlying Bennock Millpond Sand Member of the Still Branch Sand in that the Bennock Millpond consists of fine- to very fine grained sand, the sand commonly is thinly to very thinly bedded (some intervals are massive-bedded and structureless), and variably calcareous and fossiliferous with conspicuous aragonitic mollusk shells.
The underlying Congaree consists of interbedded, fine-grained sand and siliceous clay with some sections consisting mostly of variably siliceous, laminated, papery clay. The Congaree is invariably noncalcareous and nonmacro-fossiliferous.
In southern Burke County, the overlying Still Branch Sand is invariably calcareous, microfossiliferous (calcitic microfossils), and yellowish in color (due to calcareous particles).
The Congaree consists of gray, noncalcareous sand. The two formations are lithologically similar except for the invariable presence of calcite in the Still Branch Sand. Based on the presence of dinoflagellates, the environment of deposition of the Congaree Formation, in outcrop and in the shallow subsurface, is inner neritic continental shelf. Farther downdip (in more offshore sections), the Congaree was deposited in more open marine conditions, based on the presence of glauconite, phosphate, and diverse assemblages of planktonic foraminifera and dinoflagellates.
Normally, in updip and downdip lithofacies relationships, the updip, shoreward deposits consist of coarser siliciclastics, and the grain-size of the siliciclastics decrease in a downdip, seaward direction.
One would expect, then, to find nearshore sands, offshore clays, and far-offshore limestones.
In the case of the Congaree, the deposits are relatively fine updip, and coarsen downdip. There are two possible interpretations of this depositional pattern. The first interpretation is that the updip, fine-grained Congaree may have been deposited in a coastal marine, back-barrier environment.
In Burke County, the Pen Branch fault appears to mark the area of lithofacies change from argillaceous, siliceous, and carbonaceous Congaree in the north, to medium to coarse, relatively clean sand to the south. A barrier island may have developed along the crest of the upthrown, south side of the fault although no barrier island-type deposits have been identified along the projected trend of the fault. A second interpretation is that the Congaree deposits in Burke County were deposited at different times.
The oldest Congaree in northern Burke County is youngest Early Eocene, but most of the dinoflagellate floras iden-ed by Edwards are older Middle Eocene or near the Middle/Early Eocene boundary. This contrasts with the sandy, downdip Congaree in southern Burke County where there are many youngest Early Georgia, in the USGS Albany core.The known average thickness of the Congaree Formation in central and southwestern Georgia is 124 feet.In eastern Burke County, the thickness of the Congaree Formation ranges from 0 feet in the north to 62 feet (10 m)in the south (Figure 13).The average thickness of the Congaree in eastern Burke County is 38 feet (12 m).However, in the study area in northern Burke County, the Congaree Formation ranges in thickness from 0 feet in the GGS McBean core to 42 feetincore TR92-3.The average thickness of the formation is 21 feet (6.4 m).In the vicinity of the projected location of the Pen Branch fault, the Congaree Formation thins to less than 20 feet (Figure 13).From northern Burke County to the Screven County line, average dip on the top of the Congaree Formation is approximately 12 feet per mile to the southeast (Figure 14).From the vicinity of McBean Creek to the vicinity of the Pen Branch fault, average dip is approximately 14 feet per mile.Southeast of the Pen Branch fault, there is a dip reversal (Figure 14), which is followed by a return to a dip of 14 feet per mile to the county line.The Congaree Formation is distinguished from the underlying Snapp Formation by the presence of gray sand and thinly bedded to laminated clay in contrast to the top of the Snapp Formation which consists ofbleached, pyritic, very light gray to white kaolin.Deeper in the Snapp Formation, the kaolin is mottled with various shade of red, reddish brown, orange, and gray.The underlying sand is characteristically white, kaolinitic, variably micaceous, poorly sorted and medium-to coarse-grained.
In northern Burke County, the Congaree is distinguished from the overlying Bennock Millpond Sand Member of the Still Branch Sand in that the Bennock Millpond consists of fine-to very fine grained sand, the sand commonly is thinly to very thinly bedded (some intervals are massive-bedded and structureless), and variably calcareous and fossiliferous with conspicuous aragonitic mollusk shells.The underlying Congaree consists of interbedded, fine-grained sand and siliceous clay with some sections consisting mostly of variably siliceous, laminated, 38 papery clay.The Congaree is invariably noncalcareous and non macro-fossiliferous.
In southern Burke County, the overlying Still Branch Sand is invariably calcareous, microfossiliferous (calcitic microfossils), and yellowish in color (due to calcareous particles).
The Congaree consists of gray, non calcareous sand.The two formations are lithologically similar except for the invariable presence of calcite in the Still Branch Sand.Based on the presence of dinoflagellates, the environment of deposition of the Congaree Formation, in outcrop and in the shallow subsurface, is inner neritic continental shelf.Farther downdip (in more offshore sections), the Congaree was deposited in more open marine conditions, based on the presence of glauconite, phosphate, and diverse assemblages ofplanktonicforaminifera and dinoflagellates.
Normally, in updip and downdip lithofacies relationships, the updip, shoreward deposits consist of coarser siliciclastics, and the grain-size of the siliciclastics decrease in a downdip, seaward direction.
One would expect, then, to find nearshore sands, offshore clays, and far-offshore limestones.
In the case of the Congaree, the deposits are relatively fine up dip, and coarsen downdip.There are two possible interpretations of this depositional pattern.The first interpretation is that the updip, fine-grained Congaree may have been deposited in a coastal marine, back-barrier environment.
In Burke County, the Pen Branch fault appears to mark the area of lithofacies change from argillaceous, siliceous, and carbonaceous Congaree in the north, to medium to coarse, relatively clean sand to the south.A barrier island may have developed along the crest of the upthrown, south side of the fault although no barrier island-type deposits have been identified along the projected trend of the fault.A second interpretation is that the Congaree deposits in Burke County were deposited at different times.The oldest Congaree in northern Burke County is youngest Early Eocene, but most of the dinoflagellate floras identified by Edwards are older Middle Eocene or near the MiddlejEarly Eocene boundary.This contrasts with the sandy, downdip Congaree in southern Burke County where there are many youngest Early co co Savannah River Site Contour interval 20 feet Core site*Figure 13.Congaree Formation isopach (thickness distribution) map.Thicknesses are in feet.Modified from Summerour and others (1994).
Contour interval 20 feet Core site Savannah River Site o 5 miles o Contour interval 20 feet Core site*5 Figure 14.Structure contour map of the top of the Congaree Formation.
Elevations are in feet relative to mean sea level.
Eocene floras and fewer Middle Eocene floras.
The depositional patterns could be interpreted to indicate that the Congaree is a diachronous deposit. Most sedimentation first took place in a more open marine environment in southern Burke County, and later, after broaching the subtle topographic high on the Pen Branch fault, most sedimentation took place during the earliest Middle Eocene when carbonaceous, siliceous clays with interbedded fine sand was deposited in a protected coastal environment.
In Georgia (and Alabama) the only planktonic foraminifera from the Congaree Formation (and Tallahatta Formation) are of early Middle Eocene age.
This defines the typical Congaree (and Tallahatta) as being of early Middle Eocene, Lutetian, conventional early Claibornian age. Planktonic foraminiferal suites that determine the age of the Congaree and correlation of the Congaree Formation with the Tallahatta Formation include the following suite that the senior author has identified from the Tallahatta and Congaree Formations in sites from Alabama and western and central Georgia (subsurface): Morosovella aragonensis M. spinulosa Globorotalia cerroazulensis pomeroli G. bolivariana Globigerina frontosa G. linaperta G. inaequispira G. 6. eocaena G. higginsi Acarinina spinuloinflata A. broedermanni (in part Globorotalia crassata densa of Bandy, 1949)
A. pentacamerata
'(in part Globigerinoides pseudodubia of Bandy, 1949) Pseudohastigerina wilcoxensis The planktonic foraminifera restricted to the Tallahatta Formation of Alabama (C. perplicata Zone), the Congaree Formation of Georgia and the basal Cubitostrea lisbonensis Zone of the Lisbon Formation include the following Morozovella aragonensis Globigerina frontosa G. higginsi G. inaequispira Acarinina spinuloinflata A. broedermnni A. pentacamerata The association of Globorotalia cerroazulensis pomeroli and forms close to Globigerina eocaena with Globigerina higginsi, Acarinina broedermanni, Morozovella aragonensis, and Pseudohastigerina wilcoxensis (Stainforth et. al., 1975) indicates that the Tallahatta Formation, the basal part of the Lisbon Formation (C. lisbonensis Zone), and the Congaree Formation of western Georgia are in the Hantkenina aragonensis Zone (PI0 of Berggren, 1971, 1972; Haq, et al, 1987). "Anodontia"?
augustana is a useful macroguidefossil for the Congaree Formation in its type area. "Anodontia"?
augustana is also found in the Congaree Formation in the Chattahoochee River area and in the upper part of the Tallahatta Formation in Alabama (Toulmin, 1977).
Bybell and Gibson (1982) have assigned the lower part of the Tallahatta Formation of Alabama and the Congaree Formation of western Georgia to the late Early Eocene on the basis of calcareous nannofossils.
The lower pait of the Congaree and Tallahatta Formations are normally noncalcareous and, therefore, do not contain foraminifera. However, the lower part of the Congaree section in the USGS Albany core near Albany, Dougherty County, Georgia, is calcareous and contains planktonic foraminifera, that do not differ in any way from that of the upper part of the Congaree Formation in the core (except for being less well preserved). We have seen no planktonic foraminifera from either the Tallahatta Formation or Congaree Formation that can be assigned an Early Eocene age.
Those planktonic foraminifera that would be diagnostically late Early Eocene include the following Acarinina soldadoensis soldadoensis A soldadoensis angulosa Eocene tloras and fewer Middle Eocene tloras.The depositional patterns could be interpreted to indicate that the Congaree is a diachronous deposit.Most sedimentation firSt took place in a more open marine environment in southern Burke County, and later, after broaching the subtle topographic high on the Pen Branch fault, most sedimentation took place during the earliest Middle Eocene when carbonaceous, siliceous clays with interbedded fine sand was deposited in a protected coastal environment.
Age In Georgia (and Alabama)the only planktonic foraminifera from the Congaree Formation (and Tallahatta Formation) are of early Middle Eocene age.This defines the typical Congaree (and Tallahatta) as being of early Middle Eocene, Lutetian, conventional early Claibornian age.Planktonic foraminiferal suites that determine the age of the Congaree and correlation of the Congaree Formation with the Tallahatta Formation include the following suite that the senior author has identified from the Tallahatta and Congaree Formations in sites from Alabama and western and central Georgia (subsurface):
Morosovella aragonensis M.spinulosa Globorotalia cerroazulensis pomeroli G.bolivariana Globigerina frontosa G.linaperta G.inaequispira G.cf.eocaena G.higginsi Acarinina spinuloinflata A.broedermanni (in part Globorotalia crassata densa of Bandy, 1949)A.pentacamerata
"(in part Globigerinoides pseudodubia of Bandy, 1949)Pseudohastigerina wilcoxensis The planktonic foraminifera restricted to the Tallahatta Formation of Alabama (C.perplicata Zone), the Congaree Formation of Georgia and the basal Cubitostrea lisbonensis 41 Zone of the Lisbon Formation include the following:
Morozovella aragonensis Globigerina frontosa G.higginsi G.inaequispira Acarinina spinuloinflata A.broedermanni A.pentacamerata The association of Globorotalia cerroazulensis pomeroli and forms close to Globigerina eocaena with Globigerina higginsi, Acarinina broedermanni, Morozovella aragonensis, and Pseudohastigerina wilcoxensis (Stainforth et.al., 1975)indicates that the Tallahatta Formation, the basal part of the Lisbon Formation (C.lisbonensis Zone), and the Congaree Formation of western Georgia are in the Hantkenina aragonensis Zone (P10 of Berggren, 1971, 1972;Haq, et al, 1987).Anodontia?
augustana is a useful macroguidefossil for the Congaree Formation in its type area."Anodontia"?
augustana is also found in the Congaree Formation in the Chattahoochee River area and in the upper part of the Tallahatta Formation in Alabama (Toulmin, 1977).Bybell and Gibson (1982)have assigned the lower part of the Tallahatta Formation of Alabama and the Congaree Formation of western Georgia to the late Early Eocene on the basis of calcareous nannofossils.
The lower palt of the Congaree and Tallahatta Formations are normally noncalcareous and, therefore, do not contain foraminifera.
However, the lower part of the Congaree section in the USGS Albany core near Albany, Dougherty County, Georgia, is calcareous and contains planktonic foraminifera, that do not differ in any way from that of the upper part of the Congaree Formation in the core (except for being less well preserved).
We have seen noplanktonicforaminifera from either the Tallahatta Formation or Congaree Formation that can be assigned an Early Eocene age.Those planktonic foraminifera that would be diagnostically late Early Eocene include the following:
Acarinina soldadoensis soldadoensis A soldadoensis angulosa Momwvella fonnosa fonnosa M. cauccrsica M. palmeme On the other hand, Edwards (personal communication, 1993) haa identified post- Hatchetigbee, Early Eocene dinoflagellate floras from the Congaree Formation in Burke County, Georgia. She (personal communication, 1994) identified the following dinoflagellate flora taken from core samples of the Congaree Formation in Burke County, Georgia: Achilleodinium bifonnoides Adnatosphaeridium sp. Areoligem comnata Areoligem spp. Charlesdowniea tenuivirgula Cordosphaeridium fibmspinosum Cordosphaeridium gmcile Cordosphaeridium inodes Cribmperidinium giuseppei Diphyes colligerwn Eocladopyxis?
- n. sp. Fibmcysta mdiata Glaphymcysta intricata Glaphymcysta?
vicina Glaphymcysta sp. Hafniasphaem goodmanii Hafniasphaem septata Homobyblium tenuispinosum Hystrichokolpoma cinctum Hystrichokolpoma spp. Lejeunecysta sp. Lingulodinium machaemphorwn Mumtodinium jimbriatum Opemulodinium centrocarpum Pentadinium favatum Pentadinium favatum (primitive forms) Phthanoperidinium echinatum Polysphaeridium subtile Polysphaeridium whqyi Sarnlandia sp. Spiniferites spp. Turbiosphaem galatea Turbiosphaem
- d. T. galatea Wetzeliella lunaris Wetzeliella spp. According to Edwards, some dinoflagellate floras look: "... to be slightly older than the Tallahafta Formation at Little. Stave Creek and younger than Gibson and Bybell's NP 12 Talhhatta
... and ... should cwmlate to NP 13 or NP 14. ... Another scam dinoflorn (289 2% fi?et in the cwm VG-4) is indicative of the later part of Early Eocene time." The dinoflagehte flora from the core haa an age that "is noticeably younger than the type Fishburne and the flom closely resembles that of the upper part of the Ncuycuyenwy Fonnation in Virginia and Mcuyland" The stratigraphically higher dinoflagellate flora from 274-279 feet in the core VG-4 consists of the following dinoflagellates..
Areosphaeridium mutum/G. intntncata Coniosphaeridium fibmspinosum Cordosphaeridium gmcile Cribmperidinium giuseppei Glaphyrocysta divmMcata Glaphymysta?
vicina Hystntnchokolpoma sp. Opemulodinium centroccupum??
Pentadinium favatum (primitive)
Systematophom placcrcantha Wetzeliella lunaris For this sample, Edwards concluded that: "The species Hafniasvhaem noodmanii pmumably gives rise to Pentadinium favatum H. goodmanii is known mm Early Eocene material in Virginia and Mcuyland in sediments that have been correlated to nannofossil wne NP 13. Pentadinium favatum is known mm the upper part of the Tallahatta Formation and the lower part of the Lisbon Fonnation in Alabama Primitive fonns, such as found hem, suggest correlation with the upperpart of the Tallahatta I think the latest information on the Tallahatta Formation is that it includes wnes NP 12-14. So the age of this sample is likely to be NP 14 - which conveniently straddles the Early-Middle Eocene boundcuy. " According to Snipes and others (1993) most of the Congaree in the Savannah River Site in South Carolina is Early Eocene in age. According to Gohn and others (19831, the Congaree Formation:
"... contains fossil assemblages indicating an Early Eocene age, at least fir most of the unit. The lower part of the Congame is modemtely to well-sorted, fine to Morozovellaformosaformosa M.caucasica M.palmerae On the other hand, Edwards (personal communiCation, 1993)has identifiedHatchetigbee, Early Eocene dinoflagellate floras from the Congaree Formation in Burke County, Georgia.She (personal communication, 1994)identified the following dinoflagellate flora taken from core samples of the Congaree Formation in Burke County, Georgia: Achilleodinium biformoides Adnatosphaeridium sp.Areoligera coronata Areoligera spp.Charlesdowniea tenuivirgula Cordosphaeridium fibrospinosum Cordosphaeridium graeile Cordosphaeridium inodes Cribroperidinium giuseppei Diphyes colligerum Eocladopyxis?
n.sp.Fibrocysta radiata Glaphyrocysta intricata Glaphyrocysta?
vicina Glaphyrocysta sp.Ha{niasphaera goodmanii Ha{niasphaera septata Homotryblium tenuispinosum Hystrichokolpoma cinctum Hystrichokolpoma spp.14eunecysta sp.Lingulodinium machaerophorum Muratodinium fimbriatum Operculodinium centrocarpum Pentadinium favatum Pentadinium favatum (primitive forms)Phthanoperidinium echinatum Polysphaeridium subtile Polysphaeridium zoharyi Samlandia sp.Spiniferites spp.Turbiosphaera galatea Turbiosphaera d.T.galatea Wetzeliella lunaris Wetzeliella spp.According to Edwards, some dinoflagellate floras look: "...to be slightly older 42 than the Tallakatta Formation at Little Stave Creek and younger than Gibson and Bybell's NP 12 Tallakatta.
and...should correlate to NP 13 or NP 14 Another scarce dinoflora (289-294 feet in the core VG-4)is indicative of the later part of Early Eocene time." The dinoflagellate flora from the core has an age that: "is noticeably younger than the type Fishburne and the flora closely resembles that of the upper part of the Nanjemoy Formation in Virginia and Maryland." The stratigraphically higher dinoflagellate flora from 274-279 feet in the core VG-4 consists of the following dinoflagellates:
Areosphaeridium arcuatum/G.
intricata Cordosphaeridium fibrospinosum Cordosphaeridium graeile Cribroperidinium giuseppei Glaphyrocysta divaricata Glaphyrocysta?
vicina Hystrichokolpoma sp.Operculodinium centrocarpum??
Pentadinium favatum (primitive)
Systematophora placacantha Wetzeliella lunaris For this sample, Edwards concluded that: "The species Hafniasphaera goodmanii presumably gives rise to Pentadinium favatu"'-H.goodmanii is known from Early Eocene material in Virginia and Maryland in sediments that have been correlated to nannofossil zone NP 13.Pentadinium favatum is known from the upper part of the Tallahatta Formation and the lower part of the Lisbon Formation in Alabama.Primitive fonns, such as found here, suggest correlation with the upper part of the Tallahatta.
I think the latest information on the Tallahatta Formation is that it includes zones NP 12-14.So the age of this sample is likely to be NPwhich conveniently straddles the Early-Middle Eocene boundary." According to Snipes and others (1993)most of the Congaree in the Savannah River Site in South Carolina is Early Eocene in age.According to Gohn and others (1983), the Congaree Formation:
" contains fossil assemblages indicating an Early Eocene age, at least for most of the unit.The lower part of the Congaree is moderately to well-sorted, fine to coarse quartz sand with clays a few feet thick in the middle and Qt the top in places. Glauwnite, muscovite, and iron sulfide am common accessorb.
The lower part of the Congame, as the term is wed in this paper, correlates biostratigraphically with the Fishburne Formdon, a downdip donate'! Assuming that the age assignment and correlation between the Congaree and Tallahatta Formations is correct, the time intervals and lack of significant lithology differences (or sharp contacts) within the formations indicate that during the long period of Tallahatta and Congaree deposition, eustatic changes in sea level and depositional environments on the continental shelf of Georgia remained unusually stable. Still Branch Sand Definition The Still Branch Sand is a subsurface formation proposed here for a calcareous sand in Burke County. In the past, the Still Branch Sand has been called the "unnamed basal sand of the Lisbon Formation" and "unnamed sands and limestone of the Lisbon Formationn (Bechtel, 1982), and "unnamed member of the Lisbon Formationn (Gorday, 1985). We know of no references to the Still Branch Sand in the past, although it is likely that part of the surface and subsurface Santee Limestone of Fallaw and Price (1992, 1995) and D. Colquhoun and his students may be the Still Branch Sand of this report. There is one named member of the Still Branch Sand in Burke County, the Bennock MiUpond Sand (new name). The member will be described in the next section. The Still Branch Sand is considered to be a formation of the Claiborne Group because it is dominantly a calcareous, sporadically mamfderous sand similar to the lower Lisbon in southwestern Alabama. (itself a small tributary of the Savannah River) east of Girard in southern Burke County, Georgia The type locality of the formation is core VG-6 taken by Bechtel Corporation for Southern Company. The core site is at the intersection of River Road and an unimproved county road approximately
1.3 miles
(2.1 km) southeast of the River Road bridge over Sweet Water Creek. The site of core VG-6 is on the USGS 1:24,000 quadrangle map MiUett, S.C.-Ga. The type section or unit-atratotype (holo- stratotype), of the formation is the interval 328 feet to 388 feet in the core. The Still Branch Sand is disconformably overlain by the Blue Bluff Member of the Lisbon Formation at 328 feet, and is paraconformably underlain by the Congaree Formation at 388 feet. Three other core sites, VG-5 and TR92- 5, from Burke County, and the GGS Colquitt County 11, are designated reference localities (parastratotypes) for the Still Branch Sand in Georgia (Table 9, Appendix 1). Core VG-6 is chosen as a reference section because its basal bed is lithologically distinctive and a planktonic foraminiferal fauna that correlates with the lower part of the Lisbon Formation of Alabama was identified at 227 feet in the core. Core TR92-5 is designated a parastratotype because the typical calcareous sand of the Still Branch can be seen to intertongue with the updip, nearshore to coastal marine, Bennock MiUpond Sand Member. Core Colquitt County 11, near Doerun in northwestern Colquitt County, on the western flank of the Gulf Trough, is designated a reference locality and parastratotype because the general lithology of the formation is within the range of typical Still Branch and because it also represents a more downdip (offshore) lithofacies of the formation.
It is disconformably overlain by a limestone lithofacies of the Blue BlufF Member of the Lisbon Formation and conformably or paraconformably underlain by a very glauconitic to greensand lithofacies of the Congaree Formation.
Lithology The name Still Branch is taken from Still Branch, a tributary of Swwtwater Creek The Still Branch Sand is dominantly a calcareow sand but there commonly is a bed of moldic, sandy limestone or moldic, calcareous coarse quartz sand with clays a few feet thick in the middle and at the top in places.Glauconite, muscovite, and iron sulfide are common accessones.
The lower part of the Congaree, as the term is U8ed in this paper, correlates biostratigraphically with the Fishburne Formation, a downdip carbonate".
Assuming that the age assignment and correlation between the Congaree and Tallahatta Formations is correct, the time intervals and lack of significant lithology differences (or sharp contacts)within the formations indicate that during the long period of Tallahatta and Congaree deposition, eustatic changes in sea level and depositional environments on the continental shelf of Georgia remained unusually stable.Still Branch Sand Definition The Still Branch Sand is a subsurface formation proposed here for a calcareous sand in Burke County.In the past, the Still Branch Sand has been called the"unnamed basal sand of the Lisbon Formation" and"unnamed sands and limestone of the Lisbon Formation" (Bechtel, 1982), and"unnamed member of the Lisbon Formation" (Gorday, 1985).We know of no references to the Still Branch Sand in the past, although it is likely that part of the surface and subsurface Santee Limestone of Fallaw and Price (1992, 1995)and D.Colquhoun and his students may be the Still Branch Sand of this report.There is one named member of the Still Branch Sand in Burke County, the Bennock Millpond Sand (new name).The member will be described in the next section.The Still Branch Sand is considered to be a formation of the Claiborne Group because it is dominantly a calcareous, sporadically macrofossiliferous sand similar to the lower Lisbon in southwestern Alabama.Type Locality The name Still Branch is taken from Still Branch, a tributaIy of Sweetwater Creek 43 (itself a small tributaIy of the Savannah River)east of Girard in southern Burke County, Georgia.The type locality of the formation is core VG-6 taken by Bechtel Corporation for Southern Company.The core site is at the intersection of River Road and an unimproved county road approximately
1.3 miles
(2.1 kIn)southeast of the River Road bridge over Sweet Water Creek.The site of core VG-6 is on the USGS 1:24,000 quadrangle map Millett, S.C.-Ga.The type section or unit-stratotypestratotype), of the formation is the interval 328 feet to 388 feet in the core.The Still Branch Sand is disconformably overlain by the Blue Bluff Member of the Lisbon Formation at 328 feet, and is paraconformably underlain by the Congaree Formation at 388 feet.Three other core sites, VG-5 and5, from Burke County, and the GGS Colquitt County 11, are designated reference localities (parastratotypes) for the Still Branch Sand in Georgia (Table 9, Appendix 1).Core VG-5 is chosen as a reference section because its basal bed is lithologically distinctive and a planktonic foraminiferal fauna that correlates with the lower part of the Lisbon Formation of Alabama was identified at 227 feet in the core.Core TR92-5 is designated a parastratotype because the typical calcareous sand of the Still Branch can be seen to intertongue with the updip, nearshore to coastal marine, Bennock Millpond Sand Member.Core Colquitt County 11, near Doerun in northwestern Colquitt County, on the western flank.of the Gulf Trough, is designated a reference locality and parastratotype because the general lithology of the formation is within the range of typical Still Branch and because it also represents a more downdip (offshore) lithofacies of the formation.
It is disconformably overlain by a limestone lithofacies of the Blue Bluff Member of the Lisbon Formation and conformably or paraconformably underlain by a very glauconitic to greensand lithofacies of the Congaree Formation.
Lithology The Still Branch Sand is dominantly a calcareous sand but there commonly is a bed of moldic, sandy limestone or moldic, calcareous sandstone at the top of the formation. Subordinate lithic components include minor interstitial clay, rare thin beds of clay with acicular gypsum-bloom, (some beds appear to contain no clay minerals), glauconite, rare and scattered.
carbonaceous material, scattered phosphate pellets and phosphatized limestone pebbles near the top of the formation, a trace of dark minerals?, traces of pyrite in a few cores and a trace of interstitial ailica and silicified shell fragrnenta at the base of the formation in some cores. Some chalky calcitic fossils and common to abundant molluscan molds are present in the upper limestone or sandstone.
Limestone or sandstone at the top of the Still Branch Sand is typically moldic and coquinoid.
The degree of cementation is variable.
The limestone is generally indurated and the sandstone may be hard, dense and well- indurated or soft and friable. Limestone or sandstone also occur in scattered, thin beds or nodules throughout the formation in downdip areas. The limestone bed is also rubbly in places with bioclastic texture and much secondary porosity. Sand distribution is irregular or patchy in the limestone which may be the result of bioturbation. The sand is fine- to medium- grained and moderately to well-sorted.
Sand- size and sorting may be variable within any given section. In the upper limestone-sandstone bed, the quartz sand component may be medium- to coarse-grained and moderately poorly sorted. Quartz sand size and shell abundance decreases downward through the Still Branch. The sand is generally poorly consolidated to incoherent.
Core recovery is typically low in sand sections of the formation and is especially low in the lower or basal sand.
The sand is generally massive bedded and devoid of sedimentary or biogenic structures.
Sand bedding, where evident, is typically vague and the stratification crude. There are rare thin clay beds and some horizontal orientation of shells. The rare and scattered clay beds within the Still Branch have either fine, hackly fracture or are Me. In the intermediate lithofacies (in core TR92-5) calcareous sand of the undifferentiated Still Branch Sand appears to grade downd into wncalcareous sand of the Bennd Millpond Sand Member. Moat fossile consist of molds and casts of mollusks but chalky calcitic molliisk shells, small macrofossil debris, smaller foraminifera, scattered bryozoan debris, dinoflagellates and palynomorphs also occur in the lower part of the Still Branch Sand below the upper limestone-sandstone bed. Some bums from the overlying Blue Bluff can be found near the top of the formation. Still Branch color is mostly yellawish-gray, with other minor shades of gray. Clay colors range from olivegray to light olive gray. Stratigraphic Relationships The Still Branch Sand grades updip (shoreward) into the coastal marine Bennock Millpond Sand Member. Its downdip limit and western limit are not known at this time, although it does occur as far west as northwestern Colquitt County, Georgia. Because of the similarity of the limestones within the Still Branch with the Santee Limestone, and also because of comparable stratigraphic position, it is possible that the Still Branch Sand may grade laterally eastward in South Carolina into the lower part of the Santee Limestone. The Still Branch Sand overlies the Congaree Formation either conformably or paraconformably in Burke County. It is disconformably overlain by the Blue Bluff Member of the Lisbon Formation. The contact between the two formations is very pronounced, as the top of the Still Branch commonly has the appearance of a hard ground. In eastern Burke County, the thickness of the Still Branch Sand ranges from 24 feet (8 m) to approximately 80 feet (26 m) (Figure 15). The average dip of the Still Branch Sand is approximately 8 to 10 feet per mile, with a slight dip reversal near Hancock Landing and a return to the typical dip southeast of Plant Vogtle (Figure 16). The Still Branch Sand is distinguished from the underlying Congaree Formation in being invariably calcareous, micro-fossiliferous (calcitic microfossils), and yellowish in color (due to calcareous particles).
The Congaree consists sandstone at the top of the formation.
Subordinate lithic components include minor interstitial clay, rare thin beds of clay with acicular gypsum-bloom, (some beds appear to contain no clay minerals), glauconite, rare and scattered.
carbonaceous material, scattered phosphate pellets and phosphatized limestone pebbles near the top of the formation, a trace of dark minerals?, traces of pyrite in a few cores and a trace of interstitial silica and silicified shell fragments at the base of the formation in some cores.Some chalky calcitic fossils and common to abundant molluscan molds are present in the upper limestone or sandstone.
Limestone or sandstone at the top of the Still Branch Sand is typically moldic and coquinoid.
The degree of cementation is variable.The limestone is generally indurated and the sandstone may be hard, dense andindurated or soft and friable.Limestone or sandstone also occur in scattered, thin beds or nodules throughout the formation in downdip areas.The limestone bed is also rubbly in places with bioclastic texture and much secondary porosity.Sand distribution is irregular or patchy in the limestone which may be the result of bioturbation.
The sand is fine-tograined and moderately to well-sorted.size and sorting may be variable within any given section.In the upper limestone-sandstone bed, the quartz sand component may be mediurn-to coarse-grained and moderately poorly sorted.Quartz sand size and shell abundance decreases downward through the Still Branch.The sand is generally poorly consolidated to incoherent.
Core recovery is typically low in sand sections of the formation and is especially low in the lower or basal sand.The sand is generally massive bedded and devoid of sedimentary or biogenic structures.
Sand bedding, where evident, is typically vague and the stratification crude.There are rare thin clay beds and some horizontal orientation of shells.The rare and scattered clay beds within the Still Branch have either fine, hackly fracture or are fissile.In the intermediate lithofacies (in core TR92-5)calcareous sand of the undifferentiated Still Branch Sand appears to grade downward into 44 noncalcareous sand of the Bennock.Millpond Sand Member.Most fossils consist of molds and casts of mollusks but chalky calcitic mollUsk shells, small macrofossil debris, smaller foraminifera, scattered bryozoan debris, dinoflagellates and palynomorphs also occur in the lower part of the Still Branch Sand below the upper sandstone bed.Some burrows from the overlying Blue Blu1f can be found near the top of the formation.
Still Branch color is mostly gray, with other minor shades of gray.Clay colors range from olive-gray to light olive gray.Stratigraphic Relationships The Still Branch Sand grades updip (shoreward) into the coastal marine Bennock Millpond Sand Member.Its downdip limit and western limit are not known at this time, although it does occur as far west as northwestern Colquitt County, Georgia.Because of the similarity of the limestones within the Still Branch with the Santee Limestone, and also because of comparable stratigraphic position, it is possible that the Still Branch Sand may grade laterally eastward in South Carolina into the lower part of the Santee Limestone.
The Still Branch Sand overlies the Congaree Formation either conformably or paraconformably in Burke County.It is disconformably overlain by the Blue Blu1f Member of the Lisbon Formation.
The contact between the two formations is very pronounced, as the top of the Still Branch commonly has the appearance of a hard ground.In eastern Burke County, the thickness of the Still Branch Sand ranges from 24 feet (8 m)to approximately 80 feet (26 m)(Figure 15).The average dip of the Still Branch Sand is approximately 8 to 10 feet per mile, with a slight dip reversal near Hancock Landing and a return to the typical dip southeast of Plant Vogtle (Figure 16).The Still Branch Sand is distinguished from the underlying Congaree Formation in being invariably calcareous, micro-fossiliferous (calcitic microfossils), and yellowish in color (due to calcareous particles).
The Congaree consists Table 9 Stlll Branch Sand reference sections.
of gray, noncalcareous sand. The two formations are lithologically similar except for the invariable presence of calcite in the Still Branch. The Still Branch is distinguished from the overlying Blue Bluff Member of the Lisbon Formation in that the Blue Bluff is a very calcareous clay to very argillaceous limestone, typically massive-bedded in appearance but, on close inspection, is seen to be thinly bedded to laminated.
The top of the underlying Still Branch Sand is an indurated coarsely fossiliferous, moldic, sandy limestone to very calcareous sandstone.
The environment of deposition of the Still Branch Sand is interpreted to have been oflshore, inner continental shelf. Because the upper part of the formation (limestone- sandstone) extends the farthest updip where the Still Branch gradationally overlies the Bennock Millpond Sand Member, the Still Branch Sand appears to represent a transgressive half-cycle.
However, the foraminifera increase in diversity downward in the section and coarse sand in the Limestone or sandstone at the top of the formation nw indicate a regressive half-cycle.
The age of the Still Branch Sand is Middle Eocene, Claibornian, and appm to be correlative with the lower or middle part of the Lisbon Formation of Alabama (Cubitosm lisbonensis Zone to the lower part of the Cubitostma selbformis Zone). The senior author has identified the following planktonic foraminifera from the Still Branch Sand at a depth of 278 feet in core VG-8 in southern Burke County: Acarinina spinuloinflata (in part = G. bulhrooki of some authors) A pentammemta A cmssata densa (sensu Bandy, 1949) Globigerina eocaena G. primitiva G. mntosa G. cf. senni Globorotalia cf. G. renzi Globigempsis sp. Truncorotaloides rohri Pseudohustigerina micra The overlapping ranges of typical Pseudohastigerina micm, with Acarinina pentacamemta, typical Globigerina frvntosa and typical Acarinina spinuloinflata is characteristic of the Middle Eocene Globorotalia lehneri Zone or planktonic foraminiferal Zone P12.
This zone is between the Congaree Formation (Tallahatta-equivalent) and the upper Lisbon Formation (Cook Mountain-equivalent) (probably P13). In terms of calcareous nannofd zones, the Still Branch should be within upper-most NP 15 to lower-most NP 16. It is probably within the Cubitostma lisbonensis Zone of +he eastern Gulf of Mexico Coastal Plain but no fragments of Cubitostma were noted in any of the cores. Lucy Edwards of the USGS has identified the following dinoflagellate flora from the Still Branch Sand in the core VG-3: Achilleodinium bifomides Cribroperidinium giuseppei Diphyes cf. D. ficusoides Eocladopyxis
- n. sp. Hetemulaccrcysta pustulata Table 9 Stili Branch Sand reference sections.Core sa-GGS sa-Top of Bottom of...Flgure2 core number ElevatIon formatlon-formation-Table 1 Appendix 1 Move......Sea feet below feet below l.AMlI (fMt)aurfllce aurfllce VG-5 n/a 94 187 236 TR92-5 GG8-3792 235 2ZT 272 Colquitt County 11 GG8-3545 350 791 1113"n/a"*Not applicable of gray, noncalcareous sand.The two formations are lithologically similar except for the invariable presence of calcite in the Still Branch.The Still Branch is distinguished from the overlying Blue Bluff Member of the Lisbon Formation in that the Blue Bluff is a very calcareous clay to very argillaceous limestone, typically massive-bedded in appearance but, on close inspection, is seen to be thinly bedded to laminated.
The top of the underlying Still Branch Sand is an indurated coarsely fossiliferous, moldic, sandy limestone to very calcareous sandstone.
The environment of deposition of the Still Branch Sand is interpreted to have been offshore, inner continental shelf.Because the upper part of the formation sandstone) extends the farthest updip where the Still Branch gradationally overlies the Bennock Millpond Sand Member, the Still Branch Sand appears to represent a transgressive half-cycle.
However, the foraminifera increase in diversity downward in the section and coarse sand in the limestone or sandstone at the top of the formation may indicate a regressive half-cycle.
Age The age of the Still Branch Sand is Middle Eocene, Claibornian, and appears to be correlative with the lower or middle part of the Lisbon Formation of Alabama (Cubitostrea lisbonensis Zone to the lower part of the Cubitostrea sellaefonnis Zone).The senior author has identified the following planktonic foraminifera from the Still Branch Sand at a 45 depth of 278 feet in core VG-8 in southern Burke County: Acarinina spinuloinflata (in part=G.bullbrooki of some authors)A pentacamerata A crassata densa (sensu Bandy, 1949)Globigerina eocaena G.primitiva G.frontosa G.d.senni Globorotalia cr.G.renzi Globigerapsis sp.Truncorotaloides rohri Pseudohastigerina micra The overlapping ranges of typical Pseudohastigerina micra, with Acarinina pentacamerata, typical Globigerina frontosa and typical Acarinina spinuloinflata is characteristic of the Middle Eocene Globorotalia lehneri Zone or planktonic foraminiferal Zone P12.This zone is between the Congaree Formation equivalent) and the upper Lisbon Formation (Cook Mountain-equivalent)(probably PI3).In terms of calcareous nannofossil zones, the Still Branch should be within upper-most NP 15 to lower-most NP 16.It is probably within the Cubitostrea lisbonensis Zone of!he eastern Gulf of Mexico Coastal Plain but no fragments of Cubitostrea were noted in any of the cores.Lucy Edwards of the USGS has identified the following dinoflagellate flora from the Still Branch Sand in the core VG-3: Achilleodinium biformoides Cribroperidinium giuseppei Diphyes d.D.ficusoides Eocladopyxis n.sp.Heteraulacacysta pustulata Savannah River Site 5 Figure 15.Still Branch Sand isopach (thickness distribution) map.Thicknesses are in feet.miles o Contour interval 20 feet Core site*5 Savannah River Site 5 miles o Contour interval 20 feet Core site*5 N Figure 16.Structure contour map of the top of the Still Branch Sand.Elevations are in feet relative to mean sea level.
Hys tricho kolpoma rigaudiae Lingulodinium machaerophorum Membranophoridium sp. Muratodinium fimbriatum Pentadinium favatum Sarnlandia chlamydophora (var. 1) Spiniferites spp. Systematophom placacantha Thalassiphora pelagica Wetzeliella articulata (var. 1) Edwards (personal communication, 1995) considers the above flora to be "of Middle Eocene Age. ... Based on the ovemll floral similarity
... most likely correlative with the lowest Lisbon at Little Stave Creek'! Bennock Millpond Sand Member (new name)
Definition The Bennock Millpond Sand is a new member proposed here for a lithologically variable sand member of the Still Branch Sand in northern Burke County. The Bennock Millpond Sand Member grades downdip into undifferentiated Still Branch Sand in southern Burke County. The Bennock Millpond Sand Member underlies the McBean Limestone and Blue Bluff Members of the Lisbon Formation.
It is mostly a subsurface unit but it crops out in a small area along lower McBean Creek, overlooking the Savannah River flood plain near the base of "Sloan's scarp" in Burke County. The "McBean" shell bed, from which an extensive collection was made by Sloan (1908) and reported on by Veatch and Stephenson (1911) and Cooke and Shearer (1918), is apparently from the Bennock Millpond Sand Member of the Still Branch Sand and not from the overlying McBean Limestone Member of the Lisbon Formation as was previously thought. There are few other references in the literature to the Bennock Millpond Sand Member. These include the shell bed, called the McBean Formation by Veatch and Stephenson (19111, Cooke and Shearer (1918) Cooke (1936, 1943), Cooke and MacNeil (1952). LeGrand and Furcron (1966, p. 33) penetrated the Bennoclr Millpond (Beds 2 and 3) during exploratory drilling and they considered it to be McBean Formation.
We know of no other references to the Bennock Millpond Sand Member. The Bennock Millpond Sand Member is a lithologically variable unit and is composed broadly of three distinctive sand lithofacies:
1.) a fossilifemus, calcareous, fine sand; 2.) a massive-bedded to thinly bedded, noncalcareous, fine to very fine grained sand that resembles,the Peny Sand (Hetrick, 1990; Huddlestun and Hetrick, 1991; Huddlestun, 1992) and 3.) a noncalcareous, bioturbated sand.
Most commonly, the fossilifemus sand gradationally overlies the massive-bedded to thinly bedded sand. be Section The name Bennock Millpond is taken from a pond or small lake that was formed by the damming of McBean Creek where it enters the Savannah River flood plain. The type locality of the Bennock Millpond Sand Member is along McBean Creek, at the base of the northwestern part of "Sloan's scarp" (a term used by Cooke, 1936), the western valley wall of the Savannah River. The type section or unit- stratotype (holostratotype) of the member is that section (now mostly covered) exposed near the base of the valley wall. The type locality is located in the southeastern corner of the USGS 1:24,000 Mechanic Hill Ga.-S.C. and the southwestern corner of the USGS 1:24,000 Jackson S.C.-Ga. quadrangle maps. Due to erosion and vegetation cover, little can be seen of the member at the type locality.
As a result, the five cores, GGS-McBean, TR92-1, TR92-2, TR92-4, and TR92-6, are designated as reference localities (parashatotypes) for the Bennock hfillpond Sand (Table 10). Lithology Quartz sand is the dominant lithic component of the Bennock Millpond Sand Member. Subordinate lithic components includeclay that occurs interstitially, as rare clay clasts, and scattered laminae and thin beds (< 1 foot thick). The thin clay beds are finely Hystrichokolpoma rigaudiae Lingulodinium machaerophorum Membranophoridium sp.Muratodinium fimbriatum Pentadinium favatum Samlandia chlamydophora (var.1)Spiniferites spp.Systematophora placacantha Thalassiphora pelagica Wetzeliella articulata (var.1)Edwards (personal communication, 1995)considers the above tlora to be"of Middle Eocene Age....Based on the overall floral similarity
...most likely correlative with the lowest Lisbon at Little Stave Creek If.Bennock Millpond Sand Member (new name)Definition The Bennock Millpond Sand is a new member proposed here for a lithologically variable sand member of the Still Branch Sand in northern Burke County.The Bennock Millpond Sand Member grades downdip into undifferentiated Still Branch Sand in southern Burke County.The Bennock Millpond Sand Member underlies the McBean Limestone and Blue Bluff Members of the Lisbon Formation.
Itismostly a subsurface unit but it crops out in a small area along lower McBean Creek, overlooking the Savannah River flood plain near the base of"Sloan's scarp" in Burke County.The"McBean" shell bed, from which an extensive collection was made by Sloan (1908)and reported on by Veatch and Stephenson (1911)and Cooke and Shearer (1918), is apparently from the Bennock Millpond Sand Member of the Still Branch Sand and not from the overlying McBean Limestone Member of the Lisbon Formation as was previously thought.There are few other references in the literature to the Bennock.Millpond Sand Member.These include the shell bed, called the McBean Formation by Veatch and Stephenson (1911), Cooke and Shearer (1918)Cooke (1936, 1943), Cooke and MacNeil (1952).LeGrand and Furcron (1956, p.33)penetrated the Bennock 48 Millpond (Beds 2 and 3)during exploratory drilling and they considered it to be McBean Formation.
We know of no other references to the Bennock Millpond Sand Member.The Bennock Millpond Sand Member is a lithologically variable unit and is composed broadly of three distinctive sand lithofacies:
1.)a fossiliferous, calcareous, fine sand;2.)a massive-bedded to thinly bedded, noncalcareous, fine to very fine grained sand that resembles.
the Perry Sand (Hetrick., 1990;Huddlestun and Hetrick., 1991;Huddlestun, 1992)and 3.)a noncalcareous, bioturbated sand.Most commonly, the fossiliferous sand gradationally overlies the massive-bedded to thinly bedded sand.Type Section The name Bennock Millpond is taken from a pond or small lake that was formed by the damming of McBean Creek where it enters the Savannah River flood plain.The type locality of the Bennock Millpond Sand Member is along McBean Creek, at the base of the northwestern part of"Sloan's scarp" (a term used by Cooke, 1936), the western valley wall of the Savannah River.The type section orstratotype (holostratotype) of the member is that section (now mostly covered)exposed near the base of the valley wall.The type locality is located in the southeastern corner of the USGS 1:24,000 Mechanic Hill Ga.-S.C.and the southwestern corner of the USGS 1:24,000 Jackson S.C.-Ga quadrangle maps.Due to erosion and vegetation cover, little can be seen of the member at the type locality.As a result, the five cores, GGS-McBean, TR92-1, TR92-2, TR92-4, and TR92-6, are designated as reference localities (parastratotypes) for the Bennock Millpond Sand (Table 10).Lithology Quartz sand is the dominant lithic component of the Bennock Millpond Sand Member.Subordinate lithic components includeclay that occurs interstitially, as rare clay clasts, and scattered lamjnae and thin beds<<1 foot thick).The thin clay beds are finely Table 10 Bennock Millpond Sand Member reference sections.
micaceous, noncalcareous and are thinly layered to laminated and fissile. AU other lithic components are relatively minor and include calcite; aragonite; variable amounts of fine- grained mica (mica is coarser grained in the updip area); glauconite; carbonaceous material; lignitic flecks and rare lignite fragments (rare thin beds of lignite are present in the updip area); pelletal phosphate, traces of bone debris and rare phosphatic clasts (in basal beds).
Acicular stellate gypsum-bloom; acicular gypsum-bloom; cauliflower-like gypsum-bloom and rare sulphur-bloom occur on the surface of the desiccated cores.
The Bennock Millpond Sand Member is largely noncalcareous but in the upper part there are local or scattered beds of calcareous, macro-fossiliferous (both aragonitic and calcitic fossils) fine sand. The sand is mainly fine to very fine and well-sorted to very well sorted. In the lower part of the Bennock Millpond Sand Member, grain sizes and textures are more variable, ranging from fine to medium-fine, moderately sorted sand to medium to coarse, well to poorly sorted sand. Granules and pebbles occur near the base of member in the updip area. Bedding in the member varies from massive-bedded and structureless, to very crudely and vaguely stratified, to massive-bedded and bioturbated.
Many sand intervals are almost homogenized by bioturbation. Burrows are present but rare in core samples. Some of the massive-bedded and structureless sands are incoherent.
&re Sib aaa flgum 2 Tabla 1 GGS McBean TW-1 TR92-2 Bottom of member- feet below rurtace The fossil shells (mollusks) of this member are distinct from the other fossil shells in other formations in Burke County. The Bennock Millpond Sand Member contains the only well-preserved aragonitic shell fauna (Veatch and Stephenson, 1911; Cooke and Shearer, 1918) that the senior author has found from the early Tertiary in eastern Georgia. Although the McBean does contain a -few scattered lenses that contain some aragonitic shell fragments, mollusk shells of the Bennock Millpond Sand Member (both aragonitic and calcitic) are commonly thin shelled, delicate, relatively small in size, and are commonly fragmented. Preservation of the shells is variable and range from very well preserved to chalky and soft. The color of the well-preserved shells is tan to cream whereas the chalky shells are light gray to white. In general, the well- preserved aragonitic shells resemble, in size, color and preservation, those of the Lisbon Formation of western Alabama. Sand colors range through varying shades of olive-gray to yellowish-gray, shades of brown, orange, gray, brownish-black to olive black where carbonaceous, and varying shades gray. The colors of the clay beds range through shades of olive-gray to olive-black to brownish-black to yellowish brown. GGS mra number GGS-3757 GGS3874 GGS-3762 Stratigraphic Relationships The Bennock Millpond Sand Member is known to be present in eastern Georgia from Sb Ebvdon aboveM8anSm Lsvd 297 235 285 Top of nnmber- feet below 8uHace 1 86 21 1 277 Table 10 Bennock Millpond S8nd Member reference sections.Core Site GGS SIte Top of Bottom of...core ElevatIon member-member-Figure 2 number above Mean Sea feet below feet below Table 1 le¥eI surtaee surface GGS McBean GG8-3757 2!17 186 222 TR92-1 GG5-3674 235 211 245.5 TR92-2 GG8-3762 285 277 308 TR92-4 GG8-3782 192 145 182.5 TR92-6 GG8-3794 240 182 251 micaceous, noncalcareous and are thinly layered to laminated and fissile.All other lithic components are relatively minor and include calcite;aragonite; variable amounts ofgrained mica (mica is coarser grained in the up dip area);glauconite; carbonaceous material;lignitic flecksandrare lignite fragments (rare thin beds of lignite are present in the updip area);pelletal phosphate; traces of bone debris and rare phosphatic clasts (in basal beds).Acicular stellate gypsum-bloom; acicular gypsum-bloom; cauliflower-like gypsum-bloom and rare sulphur-bloom occur on the surface of the desiccated cores.The Bennock Millpond Sand Member is largely noncalcareous but in the upper part there are local or scattered beds of calcareous, macro-fossiliferous (both aragonitic and calcitic fossils)fine sand.The sand is mainly fine to very fine and well-sorted to very well sorted.In the lower part of the Bennock Millpond Sand Member, grain sizes and textures are more variable, ranging from fine to medium-fine, moderately sorted sand to medium to coarse, well to poorly sorted sand.Granules and pebbles occur near the base of member in the updip area.Bedding in the member varies from massive-bedded and structureless, to very crudely and vaguely stratified, to massive-bedded and bioturbated.
Many sand intervals are almost homogenized by bioturbation.
Burrows are present but rare in core samples.Some of the massive-bedded and structureless sands are incoherent.
49 The fossil shells (mollusks) of this member are distinct from the other fossil shells in other formations in Burke County.The Bennock Millpond Sand Member contains the only well-preserved aragonitic shell fauna (Veatch and Stephenson, 1911;Cooke and Shearer, 1918)that the senior author has found from the early Tertiary in eastern Georgia.Although the McBean does contain a*few scattered lenses that contain some aragonitic shell fragments, mollusk shells of the Bennock Millpond Sand Member (both aragonitic and calcitic)are commonly thin shelled, delicate, relatively small in size, and are commonly fragmented.
Preservation of the shells is variable and range from very well preserved to chalky and soft.The color of the well-preserved shells is tan to cream whereas the chalky shells are light gray to white.In general, thepreserved aragonitic shells resemble, in size, color and preservation, those of the Lisbon Formation of western Alabama.Sand colors range through varying shades of olive-gray to yellowish-gray, shades of brown, orange, gray, brownish-black to olive black where carbonaceous, and varying shades gray.The colors of the clay beds range through shades of olive-gray to olive-black to brownish-black to yellowish brown.Stratigraphic Relationships The Bennock Millpond Sand Member is known to be present in eastern Georgia from northern Burke County, Georgia, in the east, westward to the vicinity of Wrens in Jefferson County. In Burke County, its updip limit appears to be the vicinity of McBean Creek where it is truncated by erosion.
The downdip limit in Burke County is in the vicinity of the Pen Branch fault of Snipes and others (1992; 1993) near Hancock Landing where the Bennock Millpond Sand Member intertongues with and grades laterally into undifferentiated Still Branch Sand (Figure 5). The only clear patterns in the distribution of the three lithofacies mentioned in the section on lithology is that, where the shelly sand lithofacies is present, it occurs near the top of the Bennock Millpond section and overlies the Perry-like sand.
The Perry-like sand lithofacies in the Bennock Millpond Sand Member resemble lenses of Perry sand lithology (Huddlestun, 1992) in the upper Middle Eocene Tinker Creek Formation of Fallaw and Price (1992, 1995). However, all evidence we are aware of indicates that the Tinker Creek Formation is a nearshore, coastal marine facies of the Lisbon Formation.
The Bennock Millpond Sand Member, on the other hand, is a nearshore, coastal marine facies of the older, downdip Still Branch Sand of Georgia. The McBean and Blue Bluff Members of the Lisbon Formation overlie the Bennock Millpond Sand Member with a gradational contact over an interval of one to two feet.
This is surprising, because, farther downdip, the same contact between the Blue Bluff and the Still Branch is very distinctly disconformable.
In addition, the Bennock Millpond Sand Member and Still Branch Sand both contain lower Lisbon to upper Tallahatta dinoflagellate floras (Edwards, personal communication, 1995), indicating an Early to middle Middle Eocene age. The senior author has identified a small lower (but not lowest) Lisbon planktonic foraminiferal suite from core VG-8. The planktonic foraminiferal fauna is diagnostically Middle Eocene and is younger than the Congaree Formation and older than the Blue Bluff. There appears, then, to be a hiatus between the McBean-Blue Bluff and the underlying Bennock Millpond although the appearance of paraconformity or disconformity is certainly not obvious. This may be due to reworking and mixing of the top of the Bennock MiUpond Sand Member by infaunal organisms during the initial deposition of the Blue Bluff. Mixing of Blue Bluff and Still Branch sediments was not possible farther south because the top of the Still Branch was indurated prior to deposition of the Blue Bluff. The Bennock Millpond Sand Member overlies the Congaree Formation with uncertain contact relationships.
There are only two cores (TR92-1 and TR92-4) that have close to 100% recovery across the contact. In TR92-1 the basal bed of the Bennock Millpond Sand Member is a phosphatic, rather coarse, poorly sorted sand that abruptly overlies a thinly bedded to laminated gray clay of the bongaree.
In TR92-4, the contact appears to be a bed change with a thin bed (< 6 inches) of powdery chert at the top of the Congaree.
These contacts appear to be a disconformity and paraconformity respectively.
In all other cores that contain this contact, recovery was not good and the contacts are apparently conformable.
It is noted here that the Bennock Millpond/Congaree contact and the Still Branch/Congaree contact in Burke County, Georgia, and the Lisbon/Tallahatt.
contact in Alabama commonly appear to be gradational. Additionally, the planktonic foraminiferal faunas from the basal Lisbon Formation and the uppermost Tallahatta Formation in Alabama are in the same planktonic foraminiferal zone P10. Similarly the planktonic foraminiferal faunas from either side of the equivalent contact between Tallahatta-equivalent and lower Lisbon-equivalent formations at 1113 feet in core GGS Colquitt County 11, come from the same planktonic foraminiferal zone P10. In general, it appears that this particular formational contact in Georgia is subtle and may be locally disconformable but generally appears to be conformable and gradational (paraconformable).
The Bennock Millpond Sand Member grades laterally downdip into the Still Branch Sand in Burke County, Georgia. Based on stratigraphic position and physical correlation, the Bennock Millpond may grade laterally northern Burke County, Georgia, in the east, westward to the vicinity of Wrens in Jefferson County.In Burke County, its updip limit appears to be the vicinity of McBean Creek where it is truncated by erosion.The downdip limit in Burke County is in the vicinity of the Pen Branch fault of Snipes and others (1992;1993)near Hancock Landing where the Bennock Millpond Sand Member intertongues with and grades laterally into undifferentiated Still Branch Sand (Figure 5).The only clear patterns in the distribution of the three lithofacies mentioned in the section on lithology is that, where the shelly sand lithofacies is present, it occurs near the top of the Bennock Millpond section and overlies the Perry-like sand.The Perry-like sand lithofacies in the Bennock Millpond Sand Member resemble lenses of Perry sand lithology (Huddlestun, 1992)in the upper Middle Eocene Tinker Creek Formation of Fallaw and Price (1992, 1995).However, all evidence we are aware of indicates that the Tinker Creek Formation is a nearshore, coastal marine facies of the Lisbon Formation.
The Bennock Millpond Sand Member, on the other hand, is a nearshore, coastal marine facies of the older, downdip Still Branch Sand of Georgia.The McBean and Blue Bluff Members of the Lisbon Formation overlie the Bennock Millpond Sand Member with a gradational contact over an interval of one to two feet.This is surprising, because, farther downdip, the same contact between the Blue Bluff and the Still Branch is very distinctly disconformable.
In addition, the Bennock Millpond Sand Member and Still Branch Sand both contain lower Lisbon to upper Tallahatta dinoflagellate floras (Edwards, personal communication, 1995), indicating an Early to middle Middle Eocene age.The senior author has identified a small lower (but not lowest)Lisbon planktonic foraminiferal suite from core VG-8.The planktonic foraminiferal fauna is diagnostically Middle Eocene and is younger than the Congaree Formation and older than the Blue Bluff.There appears, then, to be a hiatus between the McBean-Blue Bluff and the underlying Bennock Millpond although the 50 appearance of paraconformity or disconformity is certainly not obvious.This may be due to reworking and mixing of the top of the Bennock Millpond Sand Member by infaunal organisms during the initial deposition of the Blue Bluff.Mixing of Blue Bluff and Still Branch sediments was not possible farther south because the top of the Still Branch was indurated prior to deposition of the Blue Bluff.The Bennock Millpond Sand Member overlies the Congaree Formation with uncertain contact relationships.
There are only two cores (TR92-1 and TR92-4)that have close to 100%recovery across the contact.In TR92-1 the basal bed of the Bennock Millpond Sand Member is a phosphatic, rather coarse, poorly sorted sand that abruptly overlies a thinly bedded to laminated gray clay of the'Congaree.
In TR92-4, the contact appears to be a bed change with a thin bed<<6 inches)of powdery chert at the top of the Congaree.These contacts appear to be a disconformity and paraconformity respectively.
In all other cores that contain this contact, recovery was not good and the contacts are apparently conformable.
It is noted here that the Bennock MillpondjCongaree contact and the Still BranchjCongaree contact in Burke County, Georgia, and the LisbonjTallahatta contact in Alabama commonly appear to be gradational.
Additionally, the planktonic foraminiferal faunas from the basal Lisbon Formation and the uppermost Tallahatta Formation in Alabama are in the same planktonic foraminiferal zone PlO.Similarly the planktonic foraminiferal faunas from either side of the equivalent contact between equivalent and lower Lisbon-equivalent formations at 1113 feet in core GGS Colquitt County 11, come from the same planktonic foraminiferal zone PI0.In general, it appears that this particular formational contact in Georgia is subtle and may be locally disconformable but generally appears to be conformable and gradational (paraconformable).
The Bennock Millpond Sand Member grades laterally downdip into the Still BranchSandin Burke County, Georgia.Based on stratigraphic position and physical correlation, the Bennock Millpond may grade laterally eastward and northeastward in South Carolina into the Warley Hill Formation.
The Bennock Millpond Sand Member is distinguished from the overlying McBean Member of the Lisbon Formation in that the latter consists of an impure, variably fine grained, sandy limestone that contains scattered calcitic fossils or molds and casts of aragonitic fossils in the limestone. Shell beds or scattered aragonitic shell fragments within the calcareous sand are typical of the Bennock Millpond.
Where the Bennock Millpond sands are noncalcareous, the sands are thinly bedded to laminated or massive-bedded with scattered lignitic and carbonaceous material.
The Bennock Millpond Sand Member is distinguished from the underlying Congaree Formation in being variably calcareous and macrofossiliferous, and in containing a significant amount of prominently and thinly bedded, fine-to very fine grained sand whereas the Congaree consists mainly of interbedded, noncalcareous, fine-grained, well-sorted sand with thinly bedded to laminated clay beds and silicified clay. Locally, the thinly bedded clay may constitute the major lithic component of the Congaree whereas clay is not known to be a significant component of the Bennock Millpond Sand Member. The Bennock Millpond Sand Member is distinguished from the dawndip-equivalent Still Branch Sand in that the Still Branch is mostly massive-bedded and structureless, consistently calcareous and macrofossiliferous to some degree (calcitic fossils), and contains a bed of moldic, sandy limestone or, more rarely, moldic, calcareous sandstone at the top of the formation.
The Bennock Millpond is a fine- to very fine grained sand that is variably calcareous with noncalcareous sand being predominant.
It is variably thin-bedded to laminated and massive- bedded and structureless.
The Bennock Millpond Sand Member consists of three different lithofacies whereas the Still Branch is consistently a calcareous, fine-medium to medium-coarse grained sand with either massive-bedded, moldic, sandy limestone or very calcareous sandstone at the top of the formation.
The Still Branch Sand is least calcareous at its base and becomes progressively more calcareous upward in the section. The sandy limestone-calcareous sandstone of the Still Branch appears to be correlative with the shell beds in the upper part of the Bennock Millpond Sand Member. Thickness of the Bennock Millpond Member ranges from 0 feet in the USGS Millers Pond core (Figure 2), to 69 feet (21 m) in core TR92-6. Average thickness in northern Burke County is close to 30 feet (9 m). The depositional environment of the Bennock Millpond Sand Member appears to have been in the inter!lngering area between the coastal marine and the inner neritic continental shelf (Still Branch Sand), and most likely represents the shoreface environment of the middle Claibornian.
The Perry-like sand lithofacies is a significant lithic component of the Bennock Millpond Sand Member. In the Fort Valley area to the southwest, Huddlestun and Hetrick (1991) ascribed the depositional environment of the Perry Sand to the shoreface based on geographic and facies position.
The shallow to middle continental shelf Lisbon Formation lies immediately to the south of the Perry Sand, and the coastal marine Mossy Creek Sand lies to the north. The outcrop band of the Perry Sand is only a few miles across, similar to the outcrop-subcrop band of the Bennock Millpond in northern Burke County. It appears that the Bennock Millpond Sand Member represents a transgressive half cycle. This interpretation is based on the assumption that shell beds occur seaward of the shoreface and represent more open marine conditions.
This is compatible with the Still Branch Sand grading downsection into the Bennock Millpond Sand Member where the two units intertongue (i.e., in TR92-4 and TR92-5). Similarly, the Still Branch Sand also appears to represent a transgressive half qcle because the formation fines and becomes more calcareous and fossiliferous upward. Edwards identified the following dinoflagellates from GGS core samples of the Bennock Millpond Sand Member from northern Burke County, Georgia: Achilleodinium biformoides eastward and northeastward in South Carolina into the Warley Hill Formation.
The Bennock Millpond Sand Member is distinguished from the overlying McBean Member of the Lisbon Formation in that the latter consists of an impure, variably fine grained, sandy limestone that contains scattered calcitic fossils or molds and casts of aragonitic fossils in the limestone.
Shell beds or scattered aragonitic shell fragments within the calcareous sand are typical of the Bennock Millpond.Where the Bennock Millpond sands are noncalcareous, the sands are thinly bedded to laminated or massive-bedded with scattered lignitic and carbonaceous material.The Bennock Millpond Sand Member is distinguished from the underlying Congaree Formation in being variably calcareous and macrofossiliferous, and in containing a significant amount of prominently and thinly bedded, fine-to very fine grained sand whereas the Congaree consists mainly of interbedded, noncalcareous, fine-grained, well-sorted sand with thinly bedded to laminated clay beds and silicified clay.Locally, the thinly bedded clay may constitute the major lithic component of the Congaree whereas clay is not known to be a significant component of the Bennock Millpond Sand Member.The Bennock Millpond Sand Member is distinguished from the downdip-equivalent Still Branch Sand in that the Still Branch is mostly massive-bedded and structureless, consistently calcareous and macrofossiliferous to some degree (calcitic fossils), and contains a bed of moldic, sandy limestone or, more rarely, moldic, calcareous sandstone at the top of the formation.
The Bennock Millpond is a fine-to very fine grained sand that is variably calcareous with noncalcareous sand being predominant.
It is variably thin-bedded to laminated andbedded and structureless.
The Bennock Millpond Sand Member consists of three different lithofacies whereas the Still Branch is consistently a calcareous, fine-medium to medium-coarse grained sand with either massive-bedded, moldic, sandy limestone or very calcareous sandstone at the top of the formation.
The Still Branch Sand is least calcareous at its base and becomes progressively more calcareous 51 upward in the section.The sandy calcareous sandstone of the Still Branch appears to be correlative with the shell beds in the upper part of the Bennock Millpond Sand Member.Thickness of the Bennock Millpond Member ranges from 0 feet in the USGS Millers Pond core (Figure 2), to 69 feet (21 m)in core TR92-6.Average thickness in northern Burke County is close to 30 feet (9 m).The depositional environment of the Bennock Millpond Sand Member appears to have been in the interfingering area between the coastal marine and the inner neritic continental shelf (Still Branch Sand), and most likely represents the shoreface environment of the middle Claibornian.
The Perry-like sand lithofacies is a significant lithic component of the Bennock Millpond Sand Member.In the Fort Valley area to the southwest, Huddlestun and Hetrick (1991)ascribed the depositional environment of the Perry Sand to the shoreface based on geographic and facies position.The shallow to middle continental shelf Lisbon Formation lies immediately to the south 0:(the Perry Sand, and the coastal marine Mossy Creek Sand lies to the north.The outcrop band of the Perry Sand is only a few miles across, similar to the outcrop-subcrop band of the Bennock Millpond in northern Burke County.It appears that the Bennock Millpond Sand Member represents a transgressive half cycle.This interpretation is based on the assumption that shell beds occur seaward of the shoreface and represent more open marine conditions.
This is compatible with the Still Branch Sand grading downsection into the Bennock Millpond Sand Member where the two units intertongue (i.e., in TR92-4 and TR92-5).Similarly, the Still Branch Sand also appears to represent a transgressive half because the formation fines and becomes more calcareous and fossiliferous upward.Age Edwards identified the following dinoflagellates from GGS core samples of the Bennock Millpond Sand Member from northern Burke County, Georgia: Achilleodinium biformoides Adnatosphaeridium?
sp. Cordosphaeridium, wile Cordosphaeridium multispinosum Cordosphaeridium fibrospinosum "Dinoptelygium cladoides sensu Morgenroth Diphyes colligemm Emmetrocysta
- n. sp. Fibrocysta sp. Glaphyrocysta cf. G. demm Glaph~cysta?
cf. G. vicina Hystntnchoko&oma rigaurdiae Lejeunecysta sp. Lentinia sp. Lingulodinium machaerophomm Microdinium sp. Muratodinium fimbriatum Nematosphaeropsis spp. Operculodinium centrocarpum Operculodinium sp. Pentadinium favatum Pentadinium favatum (including advanced forms) Pentadinium favatum (including primitive forms) Pentadinium gonifemm Pentadinium laticinctum laticinctu (1 fragment) small peridiniacean Phthanoperidinium comatum Phthanoperidinium echinatum Polysphaeridium subtile Polysphaeridium subtile or Eocladopywis
- n. sp. Polysphaeridium wharyi Samlandia chlamydophom var. 1 Samlandia mticulata Samlandia mticulifem Spiniferites spp. Systematophom placcrcantha Tectatodinium pellitum Thalassiphom pelagica Thalassiphom pelagag?ca
- n. var. Tufiiosphaem magnifica Wetzeliella articulata Wetzeliella articulata
8.1. Wetzeliella
articulata var. 1 Wetzeliella lunaris Wetzeliella/Gochtodinium 8p. According to Edwards, the upper part of the Bennock Millpond Member contains a ... "dinoflom (that) is definitely what I would call 'Tallahatta or lower Lisbon equivalent' and looks mom like the lower Lisbon.
I think the latest correlations place this in NP 14 or NP 16, earb Middle Eocene.
The sample wntains ... Middle Eomne dinocysts, dominated by Wetzeliella The environment is likely to be mom nearshore than the samples below." For the middle part of the member, her comments on the flora are as follows: 'The dinoflora looks to be the same age as the Tallahatta Formation at Little Stave Cmek.
I think it falls within NP 14, early Middle Eocene. " For the lower part of the member: "The dinoflom looks to be the same age or slightly older than the Tallahntta Formation at Little Stave Cmek and younger than Gibson and Bybell's NP 12 Tallahatta.
Thus this sample should cornlate to NP 13 or NP 14. That makes it latest Early Eocene or earliest Middle Eocene. ... I didn't see any specimens of Wetzeliella sp. " !m Based on dinoflagellates, the age of the Bennock Millpond Sand Member appears to range from earliest Early Eocene (older Tallahatta-Congaree) to the middle Middle Eocene (Cubitostrea lisbonensis Zone of Lisbon Formation).
The senior author has found no planktonic foraminifera in the Bennock Millpond Sand Member. However, a list of planktonic foraminifera from the stratigraphically equivalent Still Branch Sand was given in the previous section. The age of the Still Branch should be applicable to the age of the Bennock Millpond Sand Member. At this time, we conclude that the best approximation to the age of the Bennock Millpond Sand Member is early Middle Eocene, approximately correlative to the lower Lisbon (Cubitostrea lisbonensis Zone) of Alabama and Mississippi.
Adnatosphaeridium?
sp.Cordosphaeridium, gracile Cordosphaeridium multispinosum Cordosphaeridium fibrospinosum"Dinopterygium cladoides sensu Morgenroth Diphyes colligerum Emmetrocysta n.sp.Fibrocysta sp.Glaphyrocysta d.G.exuberans Glaphyrocysta?
d.G.vicina Hystri.chokolpoma rigaurdiae Udeunecysta sp.Lentinia sp.Lingulodinium machaerophorum Microdinium sp.Muratodinium fimbriatum Nematosphaeropsis spp.Operculodinium centrocarpum Operculodinium sp.Pentadinium favatum Pentadinium favatum (including advanced forms)Pentadinium favatum (including primitive forms)Pentadinium goniferum Pentadinium laticinctum laticinctum (1 fragment)small peridiniacean Phthanoperidinium comatum Phthanoperidinium echinatum Polysphaeridium subtile Polysphaeridium subtile or Eocladopyxis n.sp.Polysphaeridium zoharyi Samlandia chlamydophora var.1 Samlandia reticulata Samlandia reticulifera Spiniferites spp.Systematophora placacantha Tectatodinium pellitum Thalassiphora pelagica Thalassiphora pelagica n.var.Turbiosphaera magnifica Wetzeliella articulata Wetzeliella articulata s.l.Wetzeliella articulata var.1 Wetzeliella lunaris Wetzeliella/Gochtodinium sp.52 According to Edwards, the upper part of the Bennock Millpond Member contains a..."dinoflora (that)is definitely what 1 would call'Tallahatta or lower Lisbon equivalent' and looks more like the lower Lisbon.1 think the latest correlations place this in NP 14 or NP 15, early Middle Eocene.The sample contains...Middle Eocene dinocysts, dominated by Wetzeliella.
The environment is likely to be more nearshore than the samples below." For the middle part of the member, her comments on the flora are as follows: "The dinoflora looks to be the same age as the Tallahatta Formation at Little Stave Creek.1 think it falls within NP 14, early Middle Eocene." For the lower part of the member: "The dinoflora looks to be the same age or slightly older than the Tallahatta Formation at Little Stave Creek and younger than Gibson and Bybell's NP 12 Tallahatta.
Thus this sample should correlate to NP 13 or NP 14.That makes it latest Early Eocene or earliest Middle Eocene....1 didn't see any specimens of Wetzeliella sp." Based on dinoflagellates, the age of the Bennock Millpond Sand Member appears to range from earliest Early Eocene (older Tallahatta-Congaree) to the middle Middle Eocene (Cubitostrea lisbonensis Zone of Lisbon Formation).
The senior author has found no planktonic foraminifera in the Bennock Millpond Sand Member.However, a list of planktonic foraminifera from the stratigraphically equivalent Still Branch Sand was given in the previous section.The age of the Still Branch should be applicable to the age of the Bennock Millpond Sand Member.At this time, we conclude that the best approximation to the age of the Bennock Millpond Sand Member is early Middle Eocene, approximately correlative to the lower Lisbon (Cubitostrea lisbonensis Zone)of Alabama and Mississippi.
Lisbon Formation Definition The Claiborne beds and Claiborne Formation of Smith, Johnson, and Langdon (1894, p. 122-137) were elevated to group rank by Smith (1907, p. 17). The middle part of the earlier Claiborne Formation was named the Lisbon Formation for calcareous, fossilirerous, clayey sands and sandy clay exposed at Lisbon BluB on the Alabama River in Clarke County, Alabama (Smith, 1907, p. 18). Veatch and Stephenson (1911, p. 235237) recognized Claiborne Group deposits in Georgia but did not apply any of the Claiborne Group formations of Alabama (i.e, TaUahatta, Lisbon and Gosport) to the Georgia deposits.
MacNeil (1947% 194%) introduced the name Lisbon Formation in Georgia and included all Claiborne Group deposits in it that overlie the Tallahatta Formation and underlie what he believed to be Gosport Sand in the western part of the state. Subsequent to MacNeil (1947% 194%), all investigators of Tertiary deposits in western and central Georgia have recognized only the Lisbon Formation for the upper part of the Claiborne Group (Herrick, 1961; Herrick and Vorhis, 1963; Toulmin and LaMoreaux, 1963; Owen, 1963; Wait, 1963; Marsalis and Friddell, 1975; Huddlestun, 1981; Huddlestun, et al, 1988).
Herrick (1961) and Herrick and Vorhis (1963) were the first to extend the name Lisbon Formation across the entire state for Claiborne Group deposits i.., of Cook Mountain equivalency) overlying the Tallahatta Formation.
Subsequent investigators (Huddlestun, et al, 1974; Huddlestun 1981; Huddlestun, 1982; Bechtel, 1982; Gorday, 1985) also recognized the Lisbon Formation in the Savannah River area.
As used in this report, the Lisbon Formation of Georgia lithostratigraphically is the same as the upper Lisbon Formation of Alabama (CubitostreQ sellaeformis Zone-Cook Mountain equivalent). Deposits correlative with the lower part of the Lisbon (C. lisbonensis Zone), crop out only along lower McBean Creek in Burke County, Georgia, and are mostly confined to the subsurface in Georgia. The Lisbon Formation of this report differs from past usage of the name Lisbon or McBean in Georgia. The Lisbon Formation in Burke County of this report includes only those silidclastic dominated, Claiborne Group deposits that overlie the Still Branch Sand and that are overlain by the Barnwell Group. Usage of the name Lisbon by Herrick (1961) and usage in this report is similar, except that Herrick (1961) included within the Lisbon Formation sands, clays and limestones that contained what he considered to be a Lisbon or Cook Mountain foraminiferal fauna. Lithology of the typical Lisbon Formation in Alabama and Georgia is too similar to warrant formational distinction between the two states.
In addition, application of the name McBean to the Lisbon component of the Claiborne Group in Georgia is inappropriate because the distinctive lithology of the McBean in its type area in Georgia is a soft, impure limestone distinct from the typical Lisbon Formation.
The Lisbon Formation is subdivided into two formal members and an undifferentiated sand (or undifferentiated Lisbon) in this report. The McBean Limestone Member (restricted) is reduced in rank, and the Blue Bluff Member (new member) is formally described.
The McBean Limestone Member consists dominantly of sandy limestone whereas the Blue Bluff Member consists dominantly of finely and variably sandy and silty, very calcareous clay or argillaceous and silty "marl" limestone. Beds or lenses of very calcareous sand to finely sandy limestone are volumetrically minor.
The undifferentiated sand consists of calcareous, argillaceous, fine-to medium-grained sand with some finely sandy, calcareous clay beds or lenses. Undifferentiated Lisbon sand is found only in the updip and nearshore area, and it occurs spatially between the areas of typically developed McBean and Blue Bluff. me Locality The type locality of the Lisbon Formation is Lisbon Bluff on the Alabama River in Clarke County, Alabama.
The section of Lisbon Formation Definition The Claiborne beds and Claiborne Formation of Smith, Johnson, and Langdon (1894, p.122-137)were elevated to group rank by Smith (1907, p.17).The middle part of the earlier Claiborne Formation was named the Lisbon Formation for calcareous, fossiliferous, clayey sands and sandy clay exposed at Lisbon Bluff on the Alabama River in Clarke County, Alabama (Smith, 1907, p.18).Veatch and Stephenson (1911, p.235-237)recognized Claiborne Group deposits in Georgia but did not apply any of the Claiborne Group formations of Alabama (Le, Tallahatta, Lisbon and Gosport)to the Georgia deposits.MacNeil (1947a, 1947b)introduced the name Lisbon Formation in Georgia and included all Claiborne Group deposits in it that overlie the Tallahatta Formation and underlie what he believed to be Gosport Sand in the western part of the state.Subsequent to MacNeil (1947a, 1947b), all investigators of TertiaIY deposits in western and central Georgia have recognized only the Lisbon Formation for the upper part of the Claiborne Group (Herrick, 1961;Herrick and Vorhis, 1963;Toulmin and LaMoreaux, 1963;Owen, 1963;Wait, 1963;Marsalis and Friddell, 1975;Huddlestun, 1981;Huddlestun, et al, 1988).Herrick (1961)and Herrick and Vorhis (1963)were the first to extend the name Lisbon Formation across the entire state for Claiborne Group deposits (Le., of Cook Mountain equivalency) overlying the Tallahatta Formation.
Subsequent investigators (H uddlestun, et al, 1974;Huddlestun 1981;Huddlestun, 1982;Bechtel, 1982;Gorday, 1985)also recognized the Lisbon Formation in the Savannah River area.As used in this report, the Lisbon Formation of Georgia lithostratigraphically is the same as the upper Lisbon Formation of Alabama (Cubitostrea sellaeformis Zone-Cook Mountain equivalent).
Deposits correlative with the lower part of the Lisbon (C.lisbonensis Zone), crop out only along lower McBean Creek in Burke County, Georgia, and are mostly confined to the subsurface in Georgia.53 The Lisbon Formation of this report differs from past usage of the name Lisbon or McBean in Georgia.The Lisbon Formation in Burke County of this report includes only those siliciclastic dominated, Claiborne Group deposits that overlie the Still Branch Sand and that are overlain by the Barnwell Group.Usage of the name Lisbon by Herrick (1961)and usage in this report is similar, except that Herrick (1961)included within the Lisbon Formation sands, clays and limestones that contained what he considered to be a Lisbon or Cook Mountain foraminiferal fauna.Lithology of the typical Lisbon Formation in Alabama and Georgia is too similar to warrant formational distinction between the two states.In addition, application of the name McBean to the Lisbon component of the Claiborne Group in Georgia is inappropriate because the distinctive lithology of the McBean in its type area in Georgia is a soft, impure limestone distinct from the typical Lisbon Formation.
The Lisbon Formation is subdivided into two formal members and an undifferentiated sand (or undifferentiated Lisbon)in this report.The McBean Limestone Member (restricted) is reduced in rank, and the Blue Bluff Member (new member)is formally described.
The McBean Limestone Member consists dominantly of sandy limestone whereas the Blue Bluff Member consists dominantly of finely and variably sandy and silty, very calcareous clay or argillaceous and silty"marl" limestone.
Beds or lenses of very calcareous sand to finely sandy limestone are volumetrically minor.The undifferentiated sand consists of calcareous, argillaceous, fine-to medium-grained sand with some finely sandy, calcareous clay beds or lenses.Undifferentiated Lisbon sand is found only in the updip and nearshore area, and it occurs spatially between the areas of typically developed McBean and Blue Bluff.Type Locality The type locality of the Lisbon Formation is Lisbon Bluff on the Alabama River in Clarke County, Alabama.The section of Lisbon Formation exposed is the type section or unit-stratotype (holostratotype).
Lithology In Georgia, and especially in the Savannah River area, the Lisbon Formation is characteristically a calcareous, finely sandy to silty clay or "marl". The three lithic components, clay, sand, and calcite, are present in most beds or lithostratigraphic units.
However, spec5c beds may consist mostly or completely of one or two of the major lithic components. Commonly the formation is more sandy updip or shoreward, and more argillaceous and calcareous downdip where it is a very argillaceous limestone to calcareous "marl". Subordinate lithic components include mica, chert, lignitic and carbonaceous material, shells and other bioclastic debris, glauconite, pelletal phosphate, scattered vertebrate debris, pyrite, zeolite, feldspar, and dark minerals such as epidote, zircon, staurolite, garnet, tourmaline and hornblende. Smectite is the dominant clay mineral in the Lisbon Formation whereas kaolinite and illite are minor components of the clay mineral assemblage.
Clay occurs both in discrete beds and interstitially in the sand, silt, or calcitic "marl". Clay is the dominant lithic component of the Blue Bluff Member of the Lisbon. The quartz sand component of the Lisbon Formation in Georgia is generally fine-to very fine grained. However, spec5c beds, especially in the updip, nearshore area may contain medium- to coarse-grained sand. Calcite occurs in variable proportions, absent only near the top of the formation in updip areas, or in areas where the lithofacies changes into stratigraphic equivalent, coastal marine and fluvial deposits (Perry Sand and Jeffersonville member of the Huber Formation of Huddlestun and Hetrick, 1991). Calcite is most commonly present interstitially in clay in the form of minute bioclastic debris and particles.
The downdip, offshore transition from silty, calcareous clay "marl" to silty, argillaceous limestone takes place both by gradation and interfingering.
Consequently, the downdip, subsurface Lisbon is very calcareous and may be more properly considered to be an impure argillaceous limestone.
Bedding in typical Lisbon Formation is thick and massive with scattered thin beds that may form either ledges or reentrants.
Sediments within the beds generally are partially to completely homogenized by burrowing organisms so that, other than scattered burrows or traces of bioturbation, the sediment is devoid of primary sedimentary or biogenic structures.
Bedding contacts in this lithofacies are gradational and rarely sharp. Where the beds are not homogenized or bioturbated, the Lisbon Formation is characterized by thin bedding and lamination, with intricate and prominent bioturbation structures.
Degree of consolidation in the Lisbon Formation ranges from unconsolidated and incoherent to indurated and recrystallized.
Most commonly, however, the sediments are compact and resistant but unconsolidated.
Sediments of the argillaceous sand lithofacies are generally unconsolidated, but the degree of consolidation increases seaward with increasing clay and calcite content. Generally, only the very calcareous beds or limestone beds are indurated.
Consistent with this pattern, the nearshore McBean Member in Burke County is variably indurated.
The sandy, undifferentiated Lisbon is lithologically distinct from McBean and Blue BlufF. In core TR92-4, the lower 26 feet of the Lisbon consists of unconsolidated sand that is very calcareous, argillaceous, glauconitic and phosphatic (pelletal) with fine bioclastic debris.
The sand is, in part, massive-bedded and structureless, but also contains some crudely bedded or bioturbated intervals.
The sand is mostly fine and well-sorted, and the sediment is granular in texture.
The basal bed is an indurated, structureless sandy limestone.
The color of the lower part of the undifferentiated Lisbon in core TR92-4 is mostly yellowish-gray with minor dark yellowish gray but is grayish-orange where oxidized.
The limestone at the base of the member is yellowish-gray.
Lisbon Formation exposed is the type section or unit-stratotype (holostratotype).
Lithology In Georgia, and especially in the Savannah River area, the Lisbon Formation is characteristically a calcareous, finely sandy to silty clay or"marl".The three lithic components, clay, sand, and calcite, are present in most beds or lithostratigraphic units.However, specific beds may consist mostly or completely of one or two of the major lithic components.
Commonly the formation is more sandy updip or shoreward, and more argillaceous and calcareous downdip where it is a very argillaceous limestone to calcareous"marl".Subordinate lithic components include mica, chert, lignitic and carbonaceous material, shells and other bioclastic debris, glauconite, pelletal phosphate, scattered vertebrate debris, pyrite, zeolite, feldspar, and dark minerals such as epidote, zircon, staurolite, garnet, tourmaline and hornblende.
Smectite is the dominant clay mineral in the Lisbon Formation whereas kaolinite and illite are minor components of the clay mineral assemblage.
Clay occurs both in discrete beds and interstitially in the sand, silt, or calcitic"marl", Clay is the dominant lithic component of the Blue Bluff Member of the lisbon.The quartz sand component of the Lisbon Formation in Georgia is generally fine-to very fine grained.However, specific beds, especially in the up dip, nearshore area may contain medium-to coarse-grained sand.Calcite occurs in variable proportions, absent only near the top of the formation in up dip areas, or in areas where the lithofacies changes into stratigraphic equivalent, coastal marine and fluvial deposits (Perry Sand and Jeffersonville member of the Huber Formation of Huddlestun and Hetrick, 1991).Calcite is most commonly present interstitially in clay in the form of minute bioclastic debris and particles.
The downdip, offshore transition from silty, calcareous clay"marl" to silty, argillaceous limestone takes place both by gradation and interfingering.
.Consequently, the downdip, subsurface Lisbon is 54 very calcareous and may be more properly considered to be an impure argillaceous limestone.
Bedding in typical Lisbon Formation is thick and massive with scattered thin beds that may form either ledges or reentrants.
Sediments within the beds generally are partially to completely homogenized by burrowing organisms so that, other than scattered burrows or traces of bioturbation, the sediment is devoid of primary sedimentary or biogenic structures.
Bedding contacts in this lithofacies are gradational and rarely sharp.Where the beds are not homogenized or bioturbated, the Lisbon Formation is characterized by thin bedding and lamination, with intricate and prominent bioturbation structures.
Degree of consolidation in the Lisbon Formation ranges from unconsolidated and incoherent to indurated and recrystallized.
Most commonly, however, the sediments are compact and resistant but unconsolidated.
Sediments of the argillaceous sand lithofacies are generally unconsolidated, but the degree of consolidation increases seaward with increasing clay and calcite content.Generally, only the very calcareous beds or limestone beds are indurated.
Consistent with this pattern, the nearshore McBean Member in Burke County is variably indurated.
The sandy, undifferentiated Lisbon is lithologically distinct from McBean and Blue Bluff.In core TR92-4, the lower 26 feet of the Lisbon consists of unconsolidated sand that is very calcareous, argillaceous, glauconitic and phosphatic (pelletal) with fine bioclastic debris.The sand is, in part, massive-bedded and structureless, but also contains some crudely bedded or bioturbated intervals.
The sand is mostly fine and well-sorted, and the sediment is granular in texture.The basal bed is an indurated, structureless sandy limestone.
The color of the lower part of the undifferentiated Lisbon in core TR92-4 is mostly yellowish-gray with minor dark yellowish gray but is grayish-orange where oxidized.The limestone at the base of the member is yellowish-gray
.
The upper part of the Lisbon Formation in core TR92-2 is a sand but differs lithologically from the sand in the TR92-4. This lithology probably represents and interfingering between sandy McBean and undifferentiated sand.
The upper 22.5 feet of the Lisbon Formation in the core consists predominantly of unconsolidated, glauconitic, calcareous sand with a trace of mica and delicate, aragonitic shell fragments, and very sandy limestone.
It is massive-bedded and structureless, but with some indication of stratijication by horizontal orientation of shell fragments and medium to thick beds or lenses of calcareous sandstone. This sandy interval in the upper part of the Lisbon Formation appears to result from a seaward decrease in calcite content of the Lisbon and a simultaneous increase in quartz sand content.
The colors of the calcareous, sandstone beds, lenses or nodules in the Lisbon Formation in the core TR92-2 are pale yellowish orange and are gray to light gray in the unconsolidated sand. In core TR92-2, the undifferentiated Lisbon grades downward into the Blue Bluff Member by diminishing sand content and increasing clay content. Similarly, in core TR92-1, the upper 23 feet (7.0 m) of the Lisbon Formation also consists of a very sandy phase. Sand in the Lisbon is fine-grained and well-sorted, massive- bedded and structureless except for the presence of some thin lutitic limestone beds. It is slightly argillaceous, and calcareous with some calcite nodules and thin (< 1 foot thick) lutitic limestone beds. The fine sand is slightly glauconitic with fine-grained pyrite in the lower part. Both clay and calcite are minor components of the lithology and there was poor core recovery due to the incoherence of the fine- grained, well-sorted sand. The contact between the undifferentiated sand and Blue Bluff Member results from an abrupt decrease in the sand content and a simultaneous increase in clay content. Supporting the gradational character of the two lithologies, the basal bed of the Blue Bluff is more argillaceous than overlying beds, and the upper-most bed of the Blue Bluff is sandier than underlying beds. Stratigraphic Relationships Generally, the Lisbon Formation thickens in a seaward or downdip direction.
It thins updip in Georgia by gradation into the Perry Sand (Huddlestun and Hetrick, 1991) in western Georgia and, in eastern Georgia, by gradation into the Perry Sand or the Jeffersonville member of the Huber Formation (Huddlestun and Hetrick, 1991). The Tinker Creek Formation of Fallaw and Price (1992, 1995) is thought to be a coastal marine equivalent of the Lisbon Formation in the northern part of the SRS and in southern Aiken County, South Carolina. In Burke County, Georgia, known thicknesses of the Lisbon range from a minimum of 39 feet (12 m) in core TR92-6 to 84 feet (26 m) in core VG-1 (Figure 17).
Thickness of the Lisbon Formation is most variable in northern Burke County where it ranges from 39 feet (12 m) to 83 feet (25 m) in core TR92-2.
In southern Burke County, thickness of the Lisbon Formation is quite uniform, ranging from 71 feet (22 m) in core VG-7 to 84 feet (26 m) in core VG-1. Average thickness of the Lisbon Formation in eastern Burke County is approximately 71 feet (22 m). The average dip on the top of the Lisbon Formation in eastern Burke County is approximately 10 feet per mile (Figure 18) with a minor dip reversal southeast of the Pen Branch fault, with a return to a shallow, variable southeast dip, to the Screven County line. The Lisbon Formation (Cubitostrea sellaeformis Zone) contains a diverse fauna of tropical planktonic foraminifera and a diverse flora of dinoflagellates. Planktonic foraminifera inhabit only open marine watsi masses with normal salinity.
Their presence in continental shelf waters far from the continental margin of eastern North America suggests that there must have been strong offshore currents on the shelf, and possibly some upwelling off the continental shelf, to bring planktonic foraminifera into nearshore waters. This is also compatible with the reports of scattered pelletal phosphate (which is derived from cold, deep, oceanic water) in the Lisbon Formation in Georgia (Herrick, The upper part of the Lisbon Formation in core TR92-2 is a sand but differs lithologically from the sand in the TR92-4.This lithology probably represents and interfingering between sandy McBean and undifferentiated sand.The upper 22.5 feet of the Lisbon Formation in the core consists predominantly of unconsolidated, glauconitic, calcareous sand with a trace of mica and delicate, aragonitic shell fragments, and very sandy limestone.
It is massive-bedded and structureless, but with some indication of stratification by horizontal orientation of shell fragments and medium to thick beds or lenses of calcareous sandstone.
This sandy interval in the upper part of the Lisbon Formation appears to result from a seaward decrease in calcite content of the Lisbon and a simultaneous increase in quartz sand content.The colors of the calcareous, sandstone beds, lenses or nodules in the Lisbon Formation in the core TR92-2 are pale yellowish orange and are gray to light gray in the unconsolidated sand.In core TR92-2, the undifferentiated Lisbon grades downward into the Blue Bluff Member by diminishing sand content and increasing clay content.Similarly, in core TR92-1, the upper 23 feet (7.0 m)of the Lisbon Formation also consists of a very sandy phase.Sand in the Lisbon is fine-grained and well-sorted,bedded and structureless except for the presence of some thin lutitic limestone beds.It is slightly argillaceous, and calcareous with some calcite nodules and thin (<1 foot thick)lutitic limestone beds.The fine sand is slightly glauconitic with fine-grained pyrite in the lower part.Both clay and calcite are minor components of the lithology and there was poor core recovery due to the incoherence of thegrained, well-sorted sand.The contact between the undifferentiated sand and Blue Bluff Member results from an abrupt decrease in the sand content and a simultaneous increase in clay content.Supporting the gradational character of the two lithologies, the basal bed of the Blue Bluff is more argillaceous than overlying beds, and the upper-most bed of the Blue Bluff is sandier than underlying beds.55 Stratigraphic Relationships Generally, the Lisbon Formation thickens in a seaward or downdip direction.
It thins updip in Georgia by gradation into the Perry Sand (Huddlestun and Hetrick, 1991)in western Georgia and, in eastern Georgia, by gradation into the Perry Sand or the Jeffersonville member of the Huber Formation (Huddlestun and Hetrick, 1991).The Tinker Creek Formation of Fallaw and Price (1992, 1995)is thought to be a coastal marine equivalent of the Lisbon Formation in the northern part of the SRS and in southern Aiken County, South Carolina.In Burke County, Georgia, known thicknesses of the Lisbon range from a minimum of 39 feet (12 m)in core TR92-6 to 84 feet (26 m)in core VG-l (Figure 17).Thickness of the Lisbon Formation is most variable in northern Burke County where it ranges from 39 feet (12 m)to 83 feet (25 m)in core TR92-2.In southern Burke County, thickness of the Lisbon Formation is quite uniform, ranging from 71 feet (22 m)in core VG-7 to 84 feet (26 m)in core VG-l.Average thickness of the Lisbon Formation in eastern Burke County is approximately 71 feet (22 m).The average dip on the top of the Lisbon Formation in eastern Burke County is approximately 10 feet per mile (Figure 18)with a minor dip reversal southeast of the Pen Branch fault, with a return to a shallow, variable southeast dip, to the Screven County line.The Lisbon Formation (Cubitostrea sellaeformis Zone)contains a diverse fauna of tropical planktonic foraminifera and a diverse flora of dinoflagellates.
Planktonic foraminifera inhabit only open marine watf.i*masses with normal salinity.Their presence in continental shelf waters far from the continental margin of eastern North America suggests that there must have been strong offshore currents on the shelf, and possibly some upwelling off the continental shelf, to bring planktonic foraminifera into nearshore waters.This is also compatible with the reports of scattered pelletal phosphate (which is derived from cold, deep, oceanic water)in the Lisbon Formation in Georgia (Herrick, 1961). The diverse planktonic foraminifera1 faunas in the Lisbon Formation in Burke County, occur in scattered stratigraphic intervals throughout the sections, such as the exposure at the type locality of the McBean Limestone Member. However, many samples have small populations and low diversity. In Burke County, benthic foraminifera from the Lisbon Formation are characterized by low diversity and high faunal dominance (a fauna dominated by a few species).
This is consistent with an inner neritic, marine environment.
Characteristic macrofossils of the outcropping Lisbon Formation in Georgia include: Cubitostrea sellaeformis Pteropsella lapidosa Barbatia rhomboidella Benthic foraminifera include:
Cibicides westi Eponides mexicanus Asterigerina lisbonensis Larger foraminifera reported by Herrick (1961) and Herrick and Vorhis (1963) include: Asterocyclina monticellensis Lepidocyclina untillea We have identifled the following planktonic foraminifera from the Lisbon Formation in Georgia: Truncorotaloides cf. topilensis T. rohri Globorotalia spinulosa Acarinina cf. spinuloinflata (in part = G. bullbrooki of some authors) A crassata densa (sensu Bandy, 1949) A. sp. Globigerina eocaena G. cf. senni G. sp. Globorotalia cf. renzi Globigerinatheka sp. Globigeqsis sp. Pseudohastigerina micm These groups of fossils establish biostratigraphic correlation of the Lisbon Formation of Georgia with the upper Lisbon Formation of Alabama (Toulmin, 1977; Harris, 1919; Palmer, 1937; Herrick and Vorhis, 1963).
Although the nominate taxon of the Orbulinoides beckmanni Zone has not been reported from Middle Eocene Coastal Plain sediments, the abundance of Truncorotaloides rohri and the local occurrence of T. topilensis in the Lisbon Formation indicates an age close to that of PI3 of Blow (1969) and the Orbulinoides beckmanni Zone of Bolli (1957) and Stainforth and others (1975). Blue Bluff Member (new name)
Definition The name Blue Bluff Member of the Lisbon Formation has been used informally in the Savannah River area in Burke County (Huddlestun, 1981; Bechtel, 1982; Gorday, 1985; Laws, et al, 1992; Fallaw and Price, 1992, 1995) for several years.
The Blue Bluff Member is formally named and described here for the characteristically thinly bedded, bioturbated, fine-grained, very calcareous clay ("marl")
to very argillaceous limestone
("marl") lithofacies of the Lisbon Formation.
It occurs across the state from the Chattahoochee River area in western Georgia to the Savannah River area in eastern Georgia and western South Carolina.
It is largely a subsurface unit and represents an offshore, transitional phase between the nearshore, sandy undifferentiated Lisbon Formation (and McBean Limestone Member in Burke County), and an offshore, subsurface, unnamed Lisbon-equivalent limestone in Georgia. In the past, deposits here called Blue Bluff have been included in the McBean Formation (Veatch and Stephenson, 1911, p. 249; Cooke, 1936; Cooke and MacNeil, 1952; Siple, 1967) and the Lisbon Formation generally (Herrick, 1961; Herrick and Vorhis, 1963; Bechtel, 1982). Larger foraminifera reported by Herrick (1961)and Herrick and Vorhis (1963)include: Asterocyclina monticellensis Lepidocyclina antillea 1961).The diverse planktonic foraminiferal faunas in the Lisbon Formation in Burke County, occur inscatteredstratigraphic intervals throughout the sections, such as the exposure at the type locality of the McBean Limestone Member.However, many samples have small populations and low diversity.
In Burke County, benthic foraminifera from the Lisbon Formation are characterized by low diversity and high faunal dominance (a fauna dominatf"d by a few species).This is consistent with an inner neritic, marine environment.
We have identified the following planktonic foraminifera from the Lisbon Formation in Georgia: Truncorotaloides cf.topilensis T.rohri Globorotalia spinulosa Acarinina cf.spinuloinflata (in part=G.bullbrooki of some authors)A crassata densa (sensu Bandy, 1949)A.sp.Globigerina eocaena G.cf.senni G.sp.Globorotalia cf.renzi Globigerinatheka sp.Globigerapsis sp.Pseudohastigerina micra Age Characteristic macrofossils outcropping Lisbon Formation in include: Cubitostrea sellaeformis Pteropsella lapidosaBarbatiarhomhoidella Benthic foraminifera include: Cibicides westi Eponides m.exicanus Asterigerina lisbonensis of the Georgia 56 These groups of fossils establish biostratigraphic correlation of the Lisbon Formation of Georgia with the upper Lisbon Formation of Alabama (Toulmin, 1977;Harris, 1919;Palmer, 1937;Herrick and Vorhis, 1963).Although the nominate taxon of the Orbulinoides beckmanni Zone has not been reported from Middle Eocene Coastal Plain sediments, the abundance of Truncorotaloides rohri and the local occurrence of T.topilensis in the Lisbon Formation indicates an age close to that of P13 of Blow (1969)and the Orbulinoides beckmanni Zone of Bolli (1957)and Stainforth and others (1975).Blue Bluff Member (new name)Definition The name Blue Bluff Member of the Lisbon Formation has been used informally in the Savannah River area in Burke County (Huddlestun, 1981;Bechtel, 1982;Gorday, 1985;Laws, et al, 1992;Fallaw and Price, 1992, 1995)for several years.The Blue Bluff Member is formally named and described here for the characteristically thinly bedded, bioturbated, fine-grained, very calcareous clay ("marl")to very argillaceous limestone ("marl")lithofacies of the Lisbon Formation.
It occurs across the state from the Chattahoochee River area in western Georgia to the Savannah River area in eastern Georgia and western South Carolina.It is largely a subsurface unit and represents an offshore, transitional phase between the nearshore, sandy undifferentiated Lisbon Formation (and McBean Limestone Member in Burke County), and an offshore, subsurface, unnamed Lisbon-equivalent limestone in Georgia.In the past, deposits here called Blue Bluff have been included in the McBean Formation (Veatch and Stephenson, 1911, p.249;Cooke, 1936;Cooke and MacNeil, 1952;Siple, 1967)and the Lisbon Formation generally (Herrick, 1961;Herrick and Vorhis, 1963;Bechtel, 1982).
Savannah River Site 5 Figure 17.Lisbon Formation isopach (thickness distribution) map.Thicknesses are in feet.miles o Contour interval 20 feet Core site.5 N Savannah River Site 5 miles o Contour interval 20 feet Core site*5 N Figure 18.Structure contour map of the top of the Lisbon Formation.
Elevations are in feet relative to mean sea level.Modified from..mmArnur::mn nthAr!:: f1QQ4\
Type Locality The name Blue Bluff is taken from Blue Bluff on the Savannah River in Burke County, Georgia. The exposure at Blue Bluff is here designated the type ldty of the Blue Bluff Member of the Lisbon Formation (for described sections, see Veatch and Stephenson, 1911, p. 249-250, and Brantly, 1916, p. 54). Blue Bluff is approximately 2 miles (3.2 km) downriver from Hancock Landing, and is now in the southern part of the property of Georgia Power Company Plant Vogtle. The type section, or unit- stratotype (holostratotype) is the entire section exposed at Blue Bluff. Neither the lower nor upper boundaries are exposed at the type locality.
Exposures of the member at Blue Bluff and north of Blue Bluff in the river bluffs at Plant Vogtle are the only known outcrops of the member in the Savannah River area (though it was intermittently exposed during construction of the power plant at Plant Vogtle and is the foundation on which the Plant is constructed).
In the Chattahoochee River area, the Blue Bluff Member is exposed at Coheelee Creek in Early County, Georgia (Marsalis and Friddell, 1975, stop 9, p. 68-70). Four core sites (Table ll), and one outcrop are designated here as reference localities and reference sections (para- stratotypes) of the Blue Bluff Member. In the Tritium Project study area, TR92-3 and core VG-6 are designated as reference localities.
Outside the study area, USGS Laurens County core, GGS Pulaski 3, and the exposure of the Blue Bluff Member at Coheelee Creek in Early County, Georgia are designated as reference localities.
Core TR92-3 is chosen as a parastratotype because it is characteristic of the member near its lithofacies transition into the McBean Limestone Member. Core VG-6 is chosen as a parastratotype of the Blue Bluff Member because it is lithologically characteristic of the member in southern Burke County. The Blue Bluff lithology is well-developed and the core recovery was good. The Laurens County core and the Pulaski 3 are chosen as a reference sections for the Blue Bluff Member because the member is typically developed in the cores and are the only good example of the member in the Oconee River and Ocmulgee River areas respectively.
The reference locality at Coheelee Creek is in a state park, approximately
0.4 miles
east of the confluence of the creek with the Chattahoochee River, 2 miles (3.2 km) northeast of Columbia, Alabama, and 1.6 miles (2.6 km) northwest of the community of Hilton, Early County, Georgia. All the deposits exposed along Coheelee Creek in the state park compose the parastratotype of the member. Lithology The Blue Bluff Member of the Lisbon Formation is best described as a "marl", consisting dominantly of clay and calcite with minor, but irregularly distributed fine-grained quartz sand. The Blue Bluff Member typically is a thinly bedded to laminated or bioturbated, silty to finely sandy, very calcareous clay ("marl")
to very argillaceous limestone
("marl").
Although clay and calcite are the dominant lithic components of the Blue Bluff Member, it is dif6cult to determine which component is dominant.
Some beds consist primarily of clay whereas others consist of fine- grained, argillaceous limestone.
In addition, there are scattered but volumetrically minor lenses of sand in the Blue Bluff, especially at or near the top of the member. Brantley (1916, p. 54) presented one chemical analysis for a sample from Blue Bluff. The percent of carbonate in the sample was 56.1%, indicating that clay and calcite are present in nearly equal proportions. Most likely, calcite is the dominant component downdip, whereas clay is dominant updip. Fallaw and Price (1992) reported (by way of personal communication with Pa-A Thayer) that much of the Blue Bluff has more than 75% calcium carbonate from SRS cores. Smectite is the dominant clay mineral, kaolinite and illite are minor constituents (Bechtel, 1982). Calcite principally is interstitial in the form of bryozoan fragments, foraminifera, ostracods, unidentified skeletal fragments.
Undefinable microscopic calcite particles and limestone form thin beds, stratified lines of Type Locality The name Blue Bluff is taken from Blue Bluff on the Savannah River in Burke County, Georgia.The exposure at Blue Bluff is here designated the type locality of the Blue Bluff Member of the Lisbon Formation (for described sections, see Veatch and Stephenson, 1911, p.249-250, and Brantly, 1916, p.54).Blue Bluff is approximately 2 miles (3.2 km)downriver from Hancock Landing, and is now in the southern part of the property of Georgia Power Company Plant Vogtle.The type section, orstratotype (holostratotype) is the entire section exposed at Blue Bluff.Neither the lower nor upper boundaries
.are exposed at the type locality.Exposures of the member at Blue Bluff and north of Blue Bluff in the river bluffs at Plant Vogtle are the only known outcrops of the member in the Savannah River area (though it was intermittently exposed during construction of the power plant at Plant Vogtle and is the foundation on which the Plant is constructed).
In the Chattahoochee River area, the Blue Bluff Member is exposed at Coheelee Creek in Early County, Georgia (Marsalis and Friddell, 1975, stop 9, p.68-70).Four core sites (Table 11), and one outcrop are designated here as reference localities and reference sectionsstratotypes) of the Blue Bluff Member.In the Tritium Project study area, TR92-3 and core VG-6 are designated as reference localities.
Outside the study area, USGS Laurens County core, GGS Pulaski 3, and the exposure of the Blue Bluff Member at Coheelee Creek in Early County, Georgia are designated as reference localities.
Core TR92-3 is chosen as a parastratotype because it is characteristic of the member near its lithofacies transition into the McBean Limestone Member.Core VG-6 is chosen as a parastratotype of the Blue Bluff Member because it is lithologically characteristic of the member in southern Burke County.The Blue Bluff lithology is well-developed and the core recovery was good.The Laurens County core and the Pulaski 3 are chosen as a reference sections for the Blue Bluff Member because the member is typically developed in the cores and 59 are the only good example of the member in the Oconee River and Ocmulgee River areas respectively.
The reference locality at Coheelee Creek is in a state park, approximately
0.4 miles
east of the confluence of the creek with the Chattahoochee River, 2 miles (3.2 km)northeast of Columbia, Alabama, and 1.6 miles (2.6 km)northwest of the community of Hilton, Early County, Georgia.All the deposits exposed along Coheelee Creek in the state park compose the parastratotype of the member.Lithology The Blue Bluff Member of the Lisbon Formation is best described as a"marl", consisting dominantly of clay and calcite with minor, but irregularly distributed fine-grained quartz sand.The Blue Bluff Member typically is a thinly bedded to laminated or bioturbated, silty to finely sandy, very calcareous clay ("marl")to very argillaceous limestone ("marl").Although clay and calcite are the dominant lithic components of the Blue Bluff Member, it is difficult to determine which component is dominant.Some beds consist primarily of clay whereas others consist ofgrained, argillaceous limestone.
In addition, there are scattered but volumetrically minor lenses of sand in the Blue Bluff, especially at or near the top of the member.Brantley (1916, p.54)presented one chemical analysis for a sample from Blue Bluff.The percent of carbonate in the sample was 56.1%, indicating that clay and calcite are present in nearly equal proportions.
Most likely, calcite is the dominant component downdip, whereas clay is dominant updip.Fallaw and Price (1992)reported (by way of personal communication withThayer)that much of the Blue Bluff has more than 75%calcium carbonate from SRS cores.Smectite is the dominant clay mineral, kaolinite and illite are minor constituents (Bechtel, 1982).Calcite principally is interstitial in the form of bryozoan fragments, foraminifera, ostracods, unidentified skeletal fragments.
Undefinable microscopic calcite particles and limestone form thin beds, stratified lines of Table 11 Blue Bluff Member reference sections.
Core Sb see Flgure 2 Table 1 GGS Laurens Countv calcite nodules, and irregularly distributed calcite nodules. Other subordinate lithic components include mica (which is commonly conspicuous), finely disseminated pyrite, lignitic flecks and fragments, heavy minerals including epidote, zircon, garnet (Bechtel, 1982); opaque minerals, glauconite, pelletal phosphate, zeolite, sodium and potassium feldspar (Na-feldspar and K- feldspar), chert, and minor calcitic, aragonitic, and phosphatic biogenic debris.
Clay-rich layers are a darker olive gray color than the sand or calcite-rich layers, which are lighter shades of olive gray. Bedding in the Blue Bluff Member, therefore, is commonly highlighted by color differences in the sediment rather than by definition by parting along bedding planes. As a result, the Blue Bluff commonly appears to be massive-bedded in outcrop and in cores, but, upon close inspection, the bedding can be clearly discerned. Bedding in the Blue Bluff Member ranges from thin to laminar, and bedding orientation varies from flat to undulatory and, rarely, to gently inclined. Bioturbation ranges from minor rupturing of stratification to complete homogenization.
The Blue Bluff Member is generally tough, cohesive, and dense. Although nonindurated (except for calcite nodules and thin limestone beds or lenses), the typical sediment disaggregates with some difficulty in microfossil preparation.
GGS core number Pulaski 3 Battom of member-feet below surface GGS-3523 Stratigraphic Relationships Sb Elevallon above Mean Sea Level (feet) n/aU-Not applicable GGS-3111 The Blue Bluff Member of the Lisbon Formation extends across southern Georgia from the Chattahoochee River into the southern part of SRS in western South Carolina (Fallaw and Price, 1992, 1995). In eastern Burke County, Georgia, the updip limit of the Blue Bluff Member is near Hancock Landing, north of Plant Vogtle, where it intertongues with undifferentiated Lisbon sand. There are also scattered lenses of Blue Bluff lithology within the McBean Limestone Member. The downdip limit of the Blue Bluff Member in the Savannah River area is in Screven County, where the upper part of the unit consists of an unnamed, fine-grained, dense limestone.
Presumably the limestone thickens at the expense of the underlying, siliciclastic Blue Bluff Member. West of the Savannah River area, its downdip limit is uncertain but the southern-most limit could be the northern flank of the Gulf Trough. However, it seems unlikely that typical Blue Bluff Member lithology extends that far south. Conventionally the Blue Bluff Member has been correlated with the Santee Limestone of South Carolina (Fallaw and Van Price, 1992, 1995). This correlation, however, is not certain in our estimation.
We know of no evidence that the Blue Bluff grades laterally into the Santee Limestone or know of no area where the Santee and Blue Bluff are present in the same geographic area or stratigraphic position.
The Blue Bluff certainly does not appear to grade southeastward or downdip in Georgia into Top of member- feet below surface 285 247.5 300 210 Table 11 Blue Bluff Member reference sections.nfa-Not applicable Core Site GGS Site Elevation Top of member-Bottom of see Figure 2 core above Mean Sea feet below member-feet below Table 1 number Level (feet)surface surface TR92-3 GG8-3781 195 95.5 159.5 VG-6 nfa 217 255 328 GGS Laurens GGS-3523 285 247.5 312.5 County Pulaski 3 GG8-3111 300 210 315....calcite nodules, and irregularly distributed calcite nodules.Other subordinate lithic components include mica (which is commonly conspicuous), finely disseminated pyrite, lignitic flecks and fragments, heavy minerals including epidote, zircon, garnet (Bechtel, 1982);opaque minerals, glauconite, pelletal phosphate, zeolite, sodium and potassium feldspar (Na-feldspar andfeldspar), chert, and minor calcitic, aragonitic, and phosphatic biogenic debris.Clay-rich layers are a darker olive gray color than the sand or calcite-rich layers, which are lighter shades of olive gray.Bedding in the Blue Bluff Member, therefore, is commonly highlighted by color differences in the sediment rather than by definition by parting along bedding planes.As a result, the Blue Bluff commonly appears to be massive-bedded in outcrop and in cores, but, upon close inspection, the bedding can be clearly discerned.
Bedding in the Blue Bluff Member ranges from thin to laminar, and bedding orientation varies from flat to undulatory and, rarely, to gently inclined.Bioturbation ranges from minor rupturing of stratification to complete homogenization.
The Blue Bluff Member is generally tough, cohesive, and dense.Although nonindurated (except for calcite nodules and thin limestone beds or lenses), the typical sediment disaggregates with some difficulty in microfossil preparation.
Stratigraphic Relationships The Blue Bluff Member of the Lisbon Formation extends across southern Georgia from the Chattahoochee River into the southern part of SRS in western South Carolina (Fallaw and Price, 1992, 1995).In eastern Burke County, Georgia, the updip limit of the Blue Bluff Member is near Hancock Landing, north of Plant Vogtle, where it intertongues with undifferentiated Lisbon sand.There are also scattered lenses of Blue Bluff lithology within the McBean Limestone Member.The downdip limit of the Blue Bluff Member in the Savannah River area is in Screven County, where the upper part of the unit consists of an unnamed, fine-grained, dense limestone.
Presumably the limestone thickens at the expense of the underlying, siliciclastic Blue Bluff Member.West of the Savannah River area, its downdip limit is uncertain but the southern-most limit could be the northern flank of the Gulf Trough.However, it seems unlikely that typical Blue Bluff Member lithology extends that far south.Conventionally the Blue Bluff Member has been correlated with the Santee Limestone of South Carolina (Fallaw and Van Price, 1992, 1995).This correlation, however, is not certain in our estimation.
We know of no evidence that the Blue Bluff grades laterally into the Santee Limestone or know of no area where the Santee and Blue Bluff are present in the same geographic area or stratigraphic position.The Blue Bluff certainly does not appear to grade southeastward or downdip in Georgia into 60 Santee lithology.
Rather, it grades downdip into an unnamed, dense, fine-grained limestone in Screven County. In Burke County, the Blue Bluff Member disconformably overlies the Still Branch Sand, except in core TR92-6 (two miles updip from the Pen Branch fault), where it overlies the Bennock Millpond Sand Member (of the Still Branch Sand).
Normally the Blue Bluff Member disconformably underlies the Utley Limestone Member of the Clincbfield Formation, but locally, where the Utley is absent, the Blue Blutr disconformably is overlain by the Dry Branch Formation.
There is 33 feet (10 m) of Blue Bluff Member at the type section at Blue Blutr on the Savannah River. Neither the upper nor the lower contacts of the member are present in outcrop at the type locality.
In the subsurface of Burke County, the thickness of the Blue Bluff Member ranges from 64 feet (20 m) in TR92-3, to 84.5 feet (26 m) in core VG-1 taken near the community of Girard in Burke County. Based on benthic foraminifera1 faunas that are characterized by high faunal dominance and low diversity, the environment of deposition of the Blue Bluff Member is interpreted to be open marine, inner continental shelf. The scattered, relatively diverse assemblages of planktonic foraminifera, and the diverse flora of dinoflagellates indicate that the member must have had open access to outer neritic and deep ocean water masses. The Blue Bluff Member of the Lisbon Formation is Middle Eocene, Bartonian, Claibornian in age and is Cook Mountain-equivalent.
It occurs in the upper part of the Cubitostrea sellaeformis Zone although only juvenile specimens of Cubitostrea are present at Blue Bluff and in the past excavation at Plant Vogtle. Pteropsella lapidosa, a pelecypod fossil known only from the Cook Mountain and equivalents (Toulmin, 1977) is present at Blue Bluff. Characteristic planktonic foraminifera include: Truncomtaloides cf. topilensis T. rohri Globomtalia spinulosa Acarinina cf. spinuloinflata (in part = G. bullbmoki of some authors) A crassata densa (sensu Bandy, 1949) A. sp. Globigerina eocaena G. cf. senni G. sp. Globomtalia cf. renzi Globigerinatheka sp. Globigerapsis sp. Pseudohastigerina micm Cibicides westi is a characteristic benthic foraminifer of the Blue Bluff Member. Herrick (1961, p. 173) reported Asterocyclina monticellensis from deposits referred to the Blue Blutr Member of this report in well GGS-248 in Dougherty County, Georgia. Dinoflagellates identified by Edwards of the USGS include the following:
Adnatosphaeridium multispinopsum Aeriosphaeridium pectiniforme Cordosphaeridium cantharellum "Corrudinium sp. 1" of Edwards (1984) Cribmperidinium giuseppei Glaphymcysta?
vicina Heteraulacacysta porosa Hystrichokolpoma rigaudiae Hystrichosphaeropsis sp. weunecysta sp. Leninia sp. Lingulodinium machaerophorum Operculodinium sp. Pentadinium goniferum (including granulate forms)
Pentadinium goniferum/membranaceum Pentadinium/Impagidinium Samlandia chlamydophora var. 1 Spiniferites spp. Systematophora placantha Tectatodinium pellitum Thalassiphora pelagica Edwards concluded that the above "dinoflora is typical of the 'upper Lisbon to Gosport equivalent.'
late Middle Eocene, correlative to NP 16 or NP 17." Welzeliella was not found in the sample, indicating the environment was offshore, continental shelf. Santee lithology.
Rather, it grades downdip into an unnamed, dense, fine-grained limestone in Screven County.In Burke County, the Blue Bluff Member disconformably overlies the Still Branch Sand, except in core TR92-6 (two miles updip from the Pen Branch fault), where it overlies the Bennock.Millpond Sand Member (of the Still Branch Sand).Normally the Blue Bluff Member disconformably underlies the Utley Limestone Member of the Clinchfield Formation, but locally, where the Utley is absent, the Blue Bluff disconformably is overlain by the Dry Branch Formation.
There is 33 feet (10 m)of Blue Bluff Member at the type section at Blue Bluff on the Savannah River.Neither the upper nor the lower contacts of the member are present in outcrop at the type locality.In the subsurface of Burke County, the thickness of the Blue Bluff Member ranges from 64 feet (20 m)in TR92-3, to 84.5 feet (26 m)in core VG-l taken near the community of Girard in Burke County.Based on benthic foraminiferal faunas that are characterized by high faunal dominance and low diversity, the environment of deposition of the Blue Bluff Member is interpreted to be open marine, inner continental shelf.The scattered, relatively diverse assemblages of planktonic foraminifera, and the diverse tlora of dinotlagellates indicate that the member must have had open access to outer neritic and deep ocean water masses.Age The Blue Bluff Member of the Lisbon Formation is Middle Eocene, Bartonian, Claibornian in age and is Cookequivalent.
It occurs in the upper part of the Cubitostrea sellaeformis Zone although only juvenile specimens of Cubitostrea are present at Blue Bluff and in the past excavation at Plant Vogtle.Pteropsella lapidosa, a pelecypod fossil known only from the Cook Mountain and equivalents (Toulmin, 1977)is present at Blue Bluff.Characteristic planktonic foraminifera include: Truncorotaloides d.topilensis T.rohri 61 Globorotalia spinulosa Acarinina d.spinuloinflata (in part=G.bullbrooki of some authors)A crassata densa (sensu Bandy, 1949)A.sp.Globigerina eocaena G.d.senni G.sp.Globorotalia d.renzi Globigerinatheka sp.Globigerapsis sp.Pseudohastigerina micra Cibicides westi is a characteristic benthic foraminifer of the Blue Bluff Member.Herrick (1961, p.173)reported Asterocyclina monticellensis from deposits referred to the Blue Bluff Member of this report in well GGS-248 in Dougherty County, Georgia.Dinotlagellates identified by Edwards of the USGS include the following:
Adnatosphaeridium multispinopsum Aeriosphaeridium pectiniforme Cordosphaeridium cantharellum"Corrudinium sp.1" of Edwards (1984)Cribroperidinium giuseppei Glaphyrocysta?
vicina Heteraulacacysta porosa Hystrichokolpoma rigaudiae Hysmchosphaeropsis sp.14eunecysta sp.Leninia sp.Lingulodinium machaerophorum Operculodinium sp.Pentadinium goniferum (including granulate forms)Pentadiniumgoniferum/membranaceum Pentadinium/lmpagidinium Samlandia chlamydophora var.1 Spiniferites spp.Systematophora placantha Tectatodinium pellitum Thalassiphora pelagica Edwards concluded that the above"dinotlora is typical of the'upper Lisbon to Gosport equivalent.'
late Middle Eocene, correlative to NP 16 or NP 17." Welzeliella was not found in the sample, indicating the environment was offshore, continental shelf.
McBean Limestone Member (restricted)
Definition The McBean Formation of past usage (Appendix 4) is reduced in rank to member status in this report. Its geographic extent is limited, occurring only in northern Burke and southern Richmond Counties (Hetrick, 1992). The McBean, ia the strict sense of this report, is not known to exist anywhere else in Georgia. The name McBean is retained because the unit is lithologically distinctive.
The McBean Limestone Member of the Lisbon Formation consists largely of soft to hard limestone that is variably calcarenitic, slightly and variably macro-fossiliferous, finely sandy throughout, and variably argiUaceous.
The limestone is generally thick-bedded, crudely and massive-bedded, and devoid of sedimentary or biogenic structures.
Type Locality The name McBean was taken from the community of McBean and from McBean Creek. Veatch and Stephenson (1911) did not expressly designate a specific type locality.
Their principle concept of the formation is, however, inherent in their list of measured sections (p. 242) and includes the ravines or gullies in the southern valley wall of McBean Creek in Burke County, Georgia. The section of the McBean now exposed in the ravines and gullies, approximately 0.4 to 0.5 miles (0.64 to 0.8 km) southeast to east of the McBean railroad crossing, along the south side of Ga. Hwy. 56 spur, is the principal reference section (neostratotype) of the McBean Limestone Member. Sloan (1908, p. 269-271) however, presented the most thorough measured section of this locality, and the McBean Limestone Member includes beds (0 and (g) of Sloan's section. Other measured sections of the McBean type locality are to be found in Veatch and Stephenson (1911, p. 2420), Cooke (1943, p. 56), LeGrand and Furcron (1956, p. 33), and Herrick and Counts (1968,. p. 54-57). There is currently little to be seen of the McBean Limeatone Member at the type locality, however, most of the McBean Limestone Member section is exposed at Shell Bluff on the Savannah River. Because Veatch and Stephenson (1911, p. 243-247) extensively discussed the McBean section at Shell Bluff, it stands as a reference locality (parastratotype) for the McBean Limeatone Member. Shell Bluff is located at Shell Bluff Landing on the Savannah River at the end of Ga. Hwy. 80 in Burke County, Georgia. The site of the GGS McBean core (Figure 2, Table 1) is here designated a reference locality for the McBean Limestone Member. This site is 1.2 miles (1.9 km) southeast of the exposure of the limestone in the easternmost gully of the type locality.
The section from 112 feet to approximately 186 feet is a reference section (hypostratotype) for the McBean Limestone Member.
The upper boundary stratotype is at 112 feet where the McBean Limestone Member is disconformably overlain by the Utley Limestone Member of the Clinchfield Formation.
The lower boundary stratotype is at 186 feet where the McBean paraconformably overlies the Bennock Millpond Sand. Lithology In outcrop and in nearby cores, the lithology of typical McBean is dominantly a finely sandy limestone.
In the GGS McBean core, the McBean Limeatone Member primarily consists of limeatone that is variably calcarenitic, finely sandy throughout, and variably argillaceous. Minor lithic components include variable but minor amounts of fine mica; variable and minor fine lignitic and carbonaceous debris in beds, laminae, and parting surfaces; variable and minor amounts and fine-grained glauconite (most beds are nonglauconitic); some dark minerals; common gypsum bloom on desiccated core surfaces; fine-grained and trace amounts of fine-grained pyrite; some "marl", wad and MnO, dendrites; pelletal phosphate and very fine vertebrate bone debris; minute spicules and spicule molds; and scattered, thin, hard limestone beds or lenses. McBean Limestone Member (restricted)
Definition The McBean Formation of past usage (Appendix 4)is reduced in rank to member status in this report.Its geographic extent is limited, occurring only in northern Burke and southern Richmond Counties (Hetrick, 1992).The McBean,:'n the strict sense of this report, is not known to exist anywhere else in Georgia.The name McBean is retained because the unit is lithologically distinctive.
The McBean Limestone Member of the Lisbon Formation consists largely of soft to hard limestone that is variably calcarenitic, slightly and variably macro-fossiliferous, finely sandy throughout, and variably argillaceous.
The limestone is generally thick-bedded, crudely and massive-bedded, and devoid of sedimentary or biogenic structures.
Type Locality The name McBean was taken from the community of McBean and from McBean Creek.Veatch and Stephenson (1911)did not expressly designate a specific type locality.Their principle concept of the formation is, however, inherent in their list of measured sections (p.242)and includes the ravines or gullies in the southern valley wall of McBean Creek in Burke County, Georgia.The section of the McBean now exposed in the ravines and gullies, approximately 0.4 to 0.5 miles (0.64 to 0.8 km)southeast to east of the McBean railroad crossing, along the south side of Ga.Hwy.56 spur, is the principal reference section (neostratotype) of the McBean Limestone Member.Sloan (1908, p.269-271)however, presented the most thorough measured section of this locality, and the McBean Limestone Member includes beds (f)and (g)of Sloan's section.Other measured sections of the McBean type locality are to be found in Veatch and Stephenson (1911, p.2420), Cooke (1943, p.56), LeGrand and Furcron (1956, p.33), and Herrick and Counts (1968,.p.54-57).62 There is currently little to be seen of the McBean Limestone Member at the type locality, however, most of the McBean Limestone Member section is exposed at Shell Bluff on the Savannah River.Because Veatch and Stephenson 0911, p.243-247)extensively discussed the McBean section at Shell Bluff, it stands as a reference locality (parastratotype) for the McBean Limestone Member.Shell Bluff is located at Shell Bluff Landing on the Savannah River at the end of Ga.Hwy.80 in Burke County, Georgia.The site of the GGS McBean core (Figure 2, Table 1)is here designated a reference locality for the McBean Limestone Member.This site is 1.2 miles (1.9 km)southeast of the exposure of the limestone in the easternmost gully of the type locality.The section from 112 feet to approximately 186 feet is a reference section (hypostratotype) for the McBean Limestone Member.The upper boundary stratotype is at 112 feet where the McBean Limestone Member is disconformably overlain by the Utley Limestone Member of the Clinchfield Formation.
The lower boundary stratotype is at 186 feet where the McBean paraconformably overlies the Bennock Millpond Sand.Lithology In outcrop and in nearby cores, the lithology of typical McBean is dominantly a finely sandy limestone.
In the GGS McBean core, the McBean Limestone Member primarily consists of limestone that is variably calcarenitic, finely sandy throughout, and variably argillaceous.
Minor lithic components include variable but minor amounts of fine mica;variable and minor fine lignitic and carbonaceous debris in beds, laminae, and parting surfaces;variable and minor amounts and fine-grained glauconite (most beds are nonglauconitic);
some dark minerals;common gypsum bloom on desiccated core surfaces;grained and trace amounts of fine-grained pyrite;some"marl", wad and Mn0 2 dendrites; pelletal phosphate and very fine vertebrate bone debris;minute spicules and spicule molds;and scattered, thin, hard limestone beds or lenses.
In the McBean core, the limestone is generally thick- and massively bedded, crudely stratified, and devoid of sedimentary or biogenic structures.
Some thin beds or intervals with horizontally oriented, fossil molds and casts can be found. There is some interlayering of soft, sandy limestone with thin layers of hard, indurated, fine-grained, dense, argillaceous limestone.
The limestone tends to be hard to mildly indurated, friable and brittle. In the GGS McBean core, all of the McBean Limestone Member is consolidated to some degree. However, at the type locality of the McBean and in the USGS Millers Pond core, the member consists of unconsolidated finely sandy calcarenite. From 121 feet to 138 feet in the GGS McBean core, the limestone lithology is similar to the Blue Bluff Member in that it is more argiIlaceous than the rest of the McBean section, more thin- to medium-bedded and shaley, and has minor bioturbation.
It differs from typical Blue Bluff lithology in that the bed is conspicuously sandy and indurated. Typical McBean is slightly and variably macrofossiliferous; some beds are barren of macrofossils but most beds are sparsely fossiliferous.
In some beds fossils occur in small concentrations.
Most of the macrofossils consist of molds and casts of aragonitic fossils, rare and chalky aragonitic shells and shell fragments in various stages of decomposition, and scattered calcitic fossils (oysters, scallops and barnacles).
Cubitostrea sellaeformis and rare Cmssostrea gigantissima (in place) are scattered in the limestone.
The color of unweathered or unoxidized McBean Limestone Member (dry core) ranges from light olive gray through yellowish-gray to very light gray. We have not yet identified any discrete beds of sand or clay in the McBean Limestone Member. The quartz sand component is interstitial and usually fine- to very fine grained and well-sorted, but some beds contain medium- and coarse-grained, well-rounded, moderately well to poorly sorted sand.
Typically, the texture of the McBean Limestone Member is equigranular, calcarenitic, and finely bioclastic.
The McBean Limestone Member is best developed near McBean Creek from several miles above the community of McBean to Shell Bluff. In this area, there are beds or lenses of Blue Bluff lithology within the McBean, although there is no Blue Bluff lithology in the McBean at Shell Bluff. Stratigraphic Relationships The areal extent of the McBean Limestone Member of the Lisbon Formation is small. Its northern limit in Richmond County is not currently known but it probably grades laterally a mile or two north of McBean Creek into Oconee Group sediments. The Barnwell Group disconformably overlies Oconee Group deposits a few miles north of McBean Creek in southeastern Richmond County.
The McBean outcrop extends about 15 miles (24 km) up McBean Creek from Shell Bluff, and a shorter distance up Boggy Gut Creek (Hetrick, 1992). The McBean Limestone Member grades seaward into the undifferentiated sand in the vicinity .of the Pen Branch fault near Hancock Landing. In northern Burke County, the McBean Limestone Member of the Lisbon Formation overlies the Bennock Millpond Sand with apparent conformity and gradation. In turn the McBean is overlain disconformably by the Utley Limestone Member of the Clinchfield Formation or the Dry Branch Formation.
The McBean Limestone Member of the Lisbon Formation grades laterally downdip into the Blue Bluff Member of the Lisbon Formition. The range of known thickness of the McBean Limestone Member in northern Burke County is from 74 feet (16 m) to 23 feet (7 m) (Table 12). Average total thickness of the McBean Limestone Member in northern Burke County is 52 feet (16 m). An open marine origin for the McBean Limestone Member is attested to by the presence of planktonic foraminifera and Cubitostrea sellaeformis, both of which are restricted to open marine water-mass conditions.
On the other hand, the regional distribution of the McBean is small and the lithology is dominated by calcite, a product of biological activity.
Based on the above observations, it In the McBean core, the limestone is generally thick.-and massively bedded, crudely stratified, and devoid of sedimentary or biogenic structures.
Some thin beds or intervals with horizontally oriented, fossil molds and casts can be found.There is some interlayering of soft, sandy limestone with thin layers of hard, indurated, fine-grained, dense, argillaceous limestone.
The limestone tends to be hard to mildly indurated, friable and brittle.In the GGS McBean core, all of the McBean Limestone Member is consolidated to some degree.However, at the type locality of the McBean and in the USGS Millers Pond core, the member consists of unconsolidated finely sandy calcarenite.
From 121 feet to 138 feet in the GGS McBean core, the limestone lithology is similar to the Blue Bluff Member in that it is more argillaceous than the rest of the McBean section, more thin-to medium-bedded and shaley, and has minor bioturbation.
It differs from typical Blue Bluff lithology in that the bed is conspicuously sandy and indurated.
Typical McBean is slightly and variably macrofossiliferous; some beds are barren of macrofossils but most beds are sparsely fossiliferous.
In some beds fossils occur in small concentrations.
Most of the macrofossils consist of molds and casts of aragonitic fossils, rare and chalky aragonitic shells and shell fragments in various stages of decomposition, and scattered calcitic fossils (oysters, scallops and barnacles).
Cubitostrea sellaefonnis and rare Crassostrea gigantissima (in place)are scattered in the limestone.
The color of unweathered or unoxidized McBean Limestone Member (dry core)ranges from light olive gray through yellowish-gray to very light gray.We have not yet identified any discretebedsof sand or clay in the McBean Limestone Member.The quartz sand component is interstitial and usually fine-to very fine grained and well-sorted, but some beds containand coarse-grained, well-rounded, moderately well to poorly sorted sand.Typically, the texture of the McBean Limestone Member is equigranular, calcarenitic, and finely bioclastic.
63 The McBean Limestone Member is best developed near McBean Creek from several miles above the community of McBean to Shell Bluff.In this area, there are beds or lenses of Blue Bluff lithology within the McBean, although there is no Blue Bluff lithology in the McBean at Shell Bluff.Stratigraphic Relationships The areal extent of the McBean Limestone Member of the Lisbon Formation is small.Its northern limit in Richmond County is not currently known but it probably grades laterally a mile or two north of McBean Creek into Oconee Group sediments.
The Barnwell Group disconformably overlies Oconee Group deposits a few miles north of McBean Creek in southeastern Richmond County.The McBean outcrop extends about 15 miles (24 km)up McBean Creek from Shell Bluff, and a shorter distance up Boggy Gut Creek (Hetrick, 1992).The McBean Limestone Member grades seaward into the undifferentiated sand in the vicinity'of the Pen Branch fault near Hancock Landing.In northern Burke County, the McBean Limestone Member of the Lisbon Formation overlies the Bennock Millpond Sand with apparent conformity and gradation.
In turn the McBean is overlain disconformably by the Utley Limestone Member of the Clinchfield Formation or the Dry Branch Formation.
The McBean Limestone Member of the Lisbon Formation grades laterally downdip into the Blue Bluff Member of the Lisbon Fornuition.
The range of known thickness of the McBean Limestone Member in northern Burke County is from 74 feet (16 m)to 23 feet (7 m)(Table 12).Average total thickness of the McBean Limestone Member in northern Burke County is 52 feet (16 m).An open marine origin for the McBean Limestone Member is attested to by the presence of planktonic foraminifera and Cubitostrea sellaeformis, both of which are restricted to open marine water-mass conditions.
On the other hand, the regional distribution of the McBean is small and the lithology is dominated by calcite, a product of biological activity.Based on the above observations, it Table 12 Thickness variations for the McBean Limestone Member in northern Burke County.
11 I I 11 11 GGS McBean I GGS-3757 I 74 11 I! 11 USGS Millers Pond 1 p GGS-3758 78.5 11 ~ - Core stte I GGS core number would appear that the McBean was deposited in an area that was partially cut off from a source of siliciclastics, most conspicuously by the near absence of clay. There is no indication of any sort of barrier to the open ocean because the McBean, Blue Bluff, and undifferentiated Lisbon interfinger and interlense between the vicinities of Shell Bluff and Hancock Landing.
Thlcknesa In feet The age of the McBean Limestone Member is Middle Eocene, Bartonian, upper Claibornian, and Cook Mountain-equivalent.
~ossils from the McBean useful in correlation purposes include: Truncorotaloides rohri T. cf. topilensis Globorotalia spinulosa
!I among the planktonic foraminifera, and: Cibicides westi among the benthic foraminifera.
Barnwell Group Definition The Barnwell Group consists of a series of Upper Eocene near shore to coastal marine, sandy deposits in the Fall Line hills area of central to eastern Georgia and western South Carolina.
In Burke County, Georgia, the Barnwell Group is subdivided (Figure 3) into the following formations and members (Huddlestun and Hetrick, 1978, 1986; Fallaw and Price, 1992, 1995). The basal formation of the Barnwell Group consists only of the Utley Limestone Member of the ClincMeld Formation.
The Dry Branch Formation overlies the Utley Limestone Member either paraconformably or gradationally.
In Burke County, the only mappable subdivisions of the Dry Branch Formation are the Irwinton Sand Member, which dominates the Dry Branch section in northern Burke County, and the Griffins Landing Member, which dominates the section in southern Burke County. The Twiggs Clay, a member of the Dry Branch Formation in central Georgia, is represented only by beds or lenses of Twiggs clay lithology scattered throughout the Dry Branch Formation in Burke County. These clay beds are least common in the upper part of the formation, and are most common in the lower part of the formation, especially in the basal part. Other than that, there does not appear to be any systematic pattern to the distribution of the Twiggs-type clay beds between northern and southern Burke County. The Tobacco Road Sand covers most of the upland intertluve surfaces in northern Burke County (Figure 191, but farther south and west, the upland surface is covered by the Altamaha Formation which disconformably overlies the Tobacco Road Sand in that area. Lithology The lithology of the Barnwell Group is dominated by quartz sand. Minerals or lithologies that are normally subordinate may dominate the lithology of particular beds or lenses in the group. These include day (both smectite and kaolinite), limestone, greensand, Table 12 Thickness variations for the McBean Limestone Member in northern Burke County.Core site GGS core number Thickness In feet GGS McBean GG8-3757 74 USGS Millers Pond GG8-3758 78.5 TR92-1 GG8-3674 23 TR92-2 GG8-3762 23 TR92-4 GG8-3782 62 would appear that the McBean was deposited in an area that was partially cut off from a source of siliciclastics, most conspicuously by the near absence of clay.There is no indication of any sort of barrier to the open ocean because the McBean, Blue Bluff, and undifferentiated Lisbon interfinger and interlense between the vicinities of Shell Bluff and Hancock Landing.Age The age of the McBean Limestone Member is Middle Eocene, Bartonian, upper Claibornian, and Cook Mountain-equivalent.
F'ossils from the McBean useful in correlation purposes include: Truncorotaloides rohri T.cf.topilensis Globorotalia spinulosa among the planktonic foraminifera, and: Cibicides westi among the benthic foraminifera.
Bamwell Group Definition The Barnwell Group consists of a series of Upper Eocene near shore to coastal marine, sandy deposits in the Fall Line hills area of central to eastern Georgia and western South Carolina.In Burke County, Georgia, the Barnwell Group is subdivided (Figure 3)into the following formations and members (Huddlestun and Hetrick, 1978, 1986;Fallaw and Price, 1992, 64 1995).The basal formation of the Barnwell Group consists only of the Utley Limestone Member of the Clinchfield Formation.
The Dry Branch Formation overlies the Utley Limestone Member either paraconformably or gradationally.
In Burke County, the only mappable subdivisions of the Dry Branch Formation are the Irwinton Sand Member, which dominates the Dry Branch section in northern Burke County, and the Griffins Landing Member, which dominates the section in southern Burke County.The Twiggs Clay, a member of the Dry Branch Formation in central Georgia, is represented only by beds or lenses of Twiggs clay lithology scattered throughout the Dry Branch Formation in Burke County.These clay beds are least common in the upper part of the formation, and are most common in the lower part of the formation, especially in the basal part.Other than that, there does not appear to be any systematic pattern to the distribution of the Twiggs-type clay beds between northern and southern Burke County.The Tobacco Road Sand covers most of the upland intertluve surfaces in northern Burke County (Figure 19), but farther south and west, the upland surface is covered by the Altamaha Formation which disconformably overlies the Tobacco Road Sand in that area.Lithology The lithology of the Barnwell Group is dominated by quartz sand.Minerals or lithologies that are normally subordinate may dominate the lithology of particular beds or lenses in the group.These include clay (both smectite and kaolinite), limestone, greensand, oumternmry
~IIUVIU~ Miocene Altamaha Formation Upper Eocene Tobacco Road Sand Upper Eocene Dry Branch or Cllnchfield Formation GTLE ' Middle Eocene Lisbon Formation 012345 Figure 19. Geologic map showing the extent of the Upper Eocene Barnwell Group in eastern Burke County. From Summerour and others (1994). Middle Eocene Lisbon Formation 5 4 miles23 o Upper Eocene Dry Branch or Clinchfield Formation Upper Eocene Tobacco Road Sand 1m Miocene Altamaha Formation§*Figure 19.Geologic map showing the extent of the Upper Eocene Barnwell Group in eastern Burke County.From Summerour and others (1994).
lignite, opal-cristobalite, chert, sandstone, and gravel. Shells, mica, hydrated iron oxides, and wad (hydrated MnO,) may be locally conspicuous.
Other accessory lithic components of the Barnwell include aragonitic shells, pyrite, flecks of carbonaceous matter, siliceous microfossils (diatoms and sponge spicules), and generally small marine vertebrate phosphatic bone debris such as fish teeth, scales and bones. The quartz sand of the Barnwell Group ranges from veq fine to very coarse grained and locally contains lenses of gravel and mixtures of sand and pebbles. Sorting ranges from very well to very poorly sorted. In general, very fine to medium-grained sands are well-sorted and lack any appreciable clay component.
These sands (and carbonates of the Utley Limestone Member) are highly permeable and constitute the unconfined Upper Three Runs aquifer (Summerour, et al, 1994) in Burke County. With increasing grain size, sorting commonly deteriorates, producing very poorly sorted sediments such as pebbly, coarse-grained sand with a fine-grained or clayey matrix. However, some beds or lenses of well-sorted, coarse to very coarse sand are locally common. - Typical Barnwell lithologies have prominent bedding that ranges from horizontal (thick-bedded, thin-bedded, and laminated), undulatory, and cross-bedded.
Some deposits may display little bedding, probably due to bioturbation and complete mixing of the sediments.
These include the Griffins Landing Member of the Dry Branch Formation, parts of the Tobacco Road Sand, and parts of the Utley Limestone Member.
Stratigraphic Relationships The Barnwell Group covers most of the upland surface of eastern Burke County. East and south of the study area in northern and eastern Burke County, the Barnwell Group is overlain by the Miocene Altamaha Formation. The hard, brick-red to reddish brown residuum of the Tobacco Road Sand is most commonly encountered on the upland surface, but in- stream valleys, loose to almost incoherent sands of the Dry Branch Formation cause steep valley sides. Only in northernmost Burke County are older Middle Eocene deposits exposed in the lower parts of stream valleys and along bluffs of the Savannah River. The Barnwell Group grades downdip into the Ocala Group in Screven County.
There are no other stratigraphic equivalents in Georgia In Burke County the Barnwell Group either occurs at the tops of the sections, as in the study area, or is overlain disconformably by the Miocene Altamaha Formation farther west and south. The Barnwell Group disconformably overlies the Middle Eocene McBean Limestone Member of the Lisbon Formation in northern Burke County and the Blue Bluff Member of the Lisbon Formation in central and southern Burke County. In upland, interfluve areas in Burke County, thickness of the Barnwell Group ranges from 112 feet in GGS McBean core to as much as 252 feet in core VG-2. Because of the erosion of the upper portions of the Barnwell Group, isopach and structure contour maps of the Barnwell Group formations are of questionable value and are not included in this report. Environment of deposition of the Barnwell Group ranges from littoral to shallow marine, inner neritic, continental shelf. Based on the presence, and local abundance of Crassostma gigantissirnu in addition to the absence of planktonic foraminifera in all but southernmost Burke County, the salinity of the water-masses probably was slightly brackish.
The Barnwell Group is Jacksonian, Late Eocene (Priabonian) in age (see discussion, Huddlestun and Hetrick, 1986, p. 9-12). Clinchfield Formation Utley Limestone Member Definition The Utley Limestone Member of the Clinchfield Formation was named by Huddlestun and Hetrick (1986) for a fossiliferous, sandy limestone at the base of the Barnwell Group throughout eastern Burke County. The Utley Limestone was differentiated from the Clinchfield Formation because beds or lignite, opal-cristobalite, chert, sandstone, and gravel.Shells, mica, hydrated iron oxides, and wad (hydrated Mn0 2)may be locally conspicuous.
Other accessory lithic components of the Barnwell include aragonitic shells, pyrite, flecks of carbonaceous matter, siliceous microfossils (diatoms and sponge spicules), and generally small marine vertebrate phosphatic bone debris such as fish teeth, scales and bones.The quartz sand of the Barnwell Group ranges from vel)fine to very coarse grained and locally contains lenses of gravel and mixtures of sand and pebbles.Sorting ranges from very well to very poorly sorted.In general, very fine to medium-grained sands are well-sorted and lack any appreciable clay component.
These sands (and carbonates of the Utley Limestone Member)are highly permeable and constitute the unconfined Upper Three Runs aquifer (Summerour, et aI, 1994)in Burke County.With increasing grain size, sorting commonly deteriorates, producing very poorly sorted sediments such as pebbly, coarse-grained sand with a fine-grained or clayey matrix.However, some beds or lenses of well-sorted, coarse to very coarse sand are locally common.Typical Barnwell lithologies have prominent bedding that ranges from horizontal (thick-bedded, thin-bedded, and laminated), undulatory, and cross-bedded.
Some deposits may display little bedding, probably due to bioturbation and complete mixing of the sediments.
These include the Griffins Landing Member of the Dry Branch Formation, parts of the Tobacco Road Sand, and parts of the Utley Limestone Member.Stratigraphic Relationships The Barnwell Group covers most of the upland surface of eastern Burke County.East and south of the study area in northern and eastern Burke County, the Barnwell Group is overlain by the Miocene Altamaha Formation.
The hard, brick-red to reddish brown residuum of the Tobacco Road Sand is most commonly encountered on the upland surface, butstream valleys, loose to almost incoherent sands of the Dry Branch Formation cause steep valley sides.Only in northernmost Burke County are 66 older Middle Eocene deposits exposed in the lower parts of stream valleys and along bluffs of the Savannah River.TheBarnwellGroup grades downdip into the Ocala Group in Screven County.There are no other stratigraphic equivalents in Georgia.In Burke County the Barnwell Group either occurs at the tops of the sections, as in the study area, or is overlain disconformably by the Miocene Altamaha Formation farther west and south.TheBarnwellGroup disconformably overlies the Middle Eocene McBean Limestone Member of the Lisbon Formation in northern Burke County and the Blue Bluff Member of the Lisbon Formation in central and southern Burke County.In upland, interfluve areas in Burke County, thickness of the Barnwell Group ranges from 112 feet in GGS McBean core to as much as 252 feet in core VG-2.Because of the erosion of the upper portions of the Barnwell Group, isopach and structure contour maps of the Barnwell Group formations are of questionable value and are not included in this report.Environment of deposition of theBarnwellGroup ranges from littoral to shallow marine, inner neritic, continental shelf.Based on the presence, and local abundance of Crassostrea gigantissima in addition to the absence of planktonic foraminifera in all but southernmost Burke County, the salinity of the water-masses probably was slightly brackish.Age The Barnwell Group is Jacksonian, Late Eocene (Priabonian) in age (see discussion, Huddlestun and Hetrick, 1986, p.9-12).Clinchfield Formation Utley Limestone Member Definition The Utley Limestone Member of the Clinchfield Formation was named by Huddlestun and Hetrick (1986)for a fossiliferous, sandy limestone at the base of the Barnwell Group throughout eastern Burke County.The Utley Limestone was differentiated from the Clinchfield Formation because beds or lenses of Utley Limestone lithology occur within the Clinaeld Formation in central Georgia. Similarly, beds or lenses of Clinchfield sand lithology occur within the Utley Limestone in Burke County. Type Locality The name Utley was taken from Utleys Cave at the upper end of Mallards pond in eastern Burke County. The type locality is at Utleys Cave, approximately 0.8 mile (1.3 km) southwest of Hancock Landing and on the property of Georgia Power Company Plant Vogtle. The section exposed at Utleys Cave is the type section, or unit-stratotype for the member (Huddlestun and Hetrick, 1986). Lithology The Utley Limedone Member of the Clinchfield Formation typically is a moldic, fossilifemus, variably glauconitic, variably sandy limestone. Some beds consist of calcareous sanddone or, more rarely, unconsolidatad calcareous sand. The sand is generally he- grained and well-sorted, but there are minor occurrences of coarse-grained, well-to moderately sorted sand.
Other subordinate lithic components include small, dark grains (heavy minerals?);
minor amounts of clay minerals; some unconsolidated calcarenite becLs, a trace of pelletal phosphate in southern Burke County; scattered shell fragments and other calcitic fossil debris; and rare foraminifera In southern Burke County the lower part of the formation consists of a calcareous, glauconitic sand with some ,calcareous greensand.
The associated limestone has a salt and pepper appearance because of the light colored calcarenite and dark glauconite.
Clayey, calcareous "marl" is rare in the Utley. The Utley Limestone Member is typically massive-and thick-bedded but there is some crude stratitication.
Most shell molds appear to be randomly oriented, but there is a slight tendency toward horizontal alignment in some thin intervals. Some thin bedding occurs in the sandier parts of the limestone. Except where the limestone is sandy, fractures are irregular.
The 'Utley is variably and finely to coarsely moldic, with varying degrees of secondary porosity and bioclastic texture. Some limestone beds are very he grained but not lutitic. The limestone exhibits varying degrees of consolidation. Most commonly the Utley is indurated, hard, dense and recrystallized, but some beds are only partially indurated and very friable. The Utley Limestone Member is variably fossilifemus and is subcoquinoid in some beds. Unaltered calcitic shells are locally abundant, but the original aragonitic shells generally have been leached, leaving molds and impressions.
There are also some concentrations of the oyster Cmssostrea gigantissima near the base of the member, similar to concentrations in the Riggins Mill Member (Huddlestun and Hetrick, 1986). Faunal diversity is fairly high. Most of the fossils consist of molds and casts of mollusks but include unaltered bryozoa, barnacles, crab claws and echinoids.
Also, the Utley Limestone is the eastern-most know occurrence of the Perimhua lyelli bed, and the fragments of the sand dollars are locally common. The color of the limestone is most commonly very pale orange but other colors include variable shades of yellowish-gray, olive- gray and light-grays.
Stratigraphic Relationships In Georgia, the Utley Limestone is currently known only from the Savannah River area in Burke and Screven Counties, Georgia (Huddlestun and Hetrick, 1986). However, beds or lenses of Utley-like limestone are present in the Riggins Mill Member of the Clinchfield Formation in the central Georgia Coastal Plain. Fallaw and Price (1992) have identifled the Utley Limestone in the southeastern part of SRS in Barnwell County, South Carolina, but report its absence updip in the middle part of SRS. In eastern Burke County, the Utley Limestone is locally absent due either to solution or nondeposition on topographic highs during the Jacksonian transgression. Where the Utley Limestone is present, it disconformably overlies lenses of Utley Limestone lithology occur within the Clinchfield Formation in central Georgia.Similarly, beds or lenses of Clinchfield sand lithology occur within the Utley Limestone in Burke County.Type Locality The name Utley was taken from Utleys Cave at the upper end of Mallards pond in eastern Burke County.The type locality is at Utleys Cave, approximately 0.8 mile (1.3 km)southwest of Hancock Landing and on the property of Georgia Power Company Plant Vogtle.The section exposed at Utleys Cave is the type section, or unit-stratotype for the member (Huddlestun and Hetrick, 1986).Lithology The Utley Limestone Member of the Clinchfield Formation typically is a moldic, fossiliferous, variably glauconitic, variably sandy limestone.
Some beds consist of calcareous sandstone or, more rarely, unconsolidated calcareous sand.The sand is generallygrained and well-sorted, but there are minor occurrences of coarse-grained, well-to moderately sorted sand.Other subordinate lithic components include small, dark grains (heavy minerals?);
minor amounts of clay minerals;some unconsolidated calcarenite beds;a trace of pelletal phosphate in southern Burke County;scattered shell fragments and other calcitic fossil debris;and rare foraminifera.
In southern Burke County the lower part of the formation consists of a calcareous, glauconitic sand with some'calcareous greensand.
The associated limestone has a salt and pepper appearance because of the light colored calcarenite and dark glauconite.
Clayey, calcareous"marl" is rare in the Utley.The Utley Limestone Member is typically massive-and thick-bedded but there is some crude stratification.
Most shell molds appear to be randomly oriented, but there is a slight tendency toward horizontal alignment in some thin intervals.
Some thin bedding occurs in the sandier parts of the limestone.
Except 67 where the limestone is sandy, fractures are irregular.
The Utley is variably and finely to coarsely moldic, with varying degrees of secondary porosity and bioclastic texture.Some limestone beds are very fine grained but not lutitic.The limestone exhibits varying degrees of consolidation.
Most commonly the Utley is indurated, hard, dense and recrystallized, but some beds are only partially indurated and very friable.The Utley Limestone Member is variably fossiliferous and is subcoquinoid in some beds.Unaltered calcitic shells are locally abundant, but the original aragonitic shells generally have been leached, leaving molds and impressions.
There are also some concentrations of the oyster Crassostrea gigantissima near the base of the member, similar to concentrations in the Riggins Mill Member (Huddlestun and Hetrick, 1986).Faunal diversity is fairly high.Most of the fossils consist of molds and casts of mollusks but include unaltered bryozoa, barnacles, crab claws and echinoids.
Also, the Utley Limestone is the eastern-most known occurrence of the Periarchus lyelli bed, and the fragments of the sand dollars are locally common.The color of the limestone is most commonly very pale orange but other colors include variable shades of yellowish-gray,gray and light-grays.
Stratigraphic Relationships In Georgia, the Utley Limestone is currently known only from the Savannah River area in Burke and Screven Counties, Georgia (Huddlestun and Hetrick, 1986).However, beds or lenses of Utley-like limestone are present in the Riggins Mill Member of the Clinchfield Formation in the central Georgia Coastal Plain.Fallaw and Price (1992)have identified the Utley Limestone in the southeastern part of SRS in Barnwell County, South Carolina, but report its absence updip in the middle part of SRS.In eastern Burke County, the Utley Limestone is locally absent due either to solution or nondeposition on topographic highs during the Jacksonian transgression.
Where the Utley Limestone is present, it disconformably overlies the McBean Member and undifferentiated Lisbon Formation in northern Burke County, and disconformably overlies the Blue Bluff Member in central and southern Burke County. The Utley in turn is overlain with apparent conformity by the Dry Branch Formation, but the contact is generally sharp.
In northern Burke County, Utley Limestone ranges in thickness from 0 feet (where absent) to 13 feet (4 m) at the type locality.
Its average thickness in northern Burke County Cbased on 8 sites) is approximately 7 feet (2 m). The Utley limestone is systematically thicker in southern Burke County where it ranges from 10 feet (3 m) in core VG-4 to 34 feet (10 m) in core VG-8. Fallaw and Price (1992, 1995) reported 30 feet (9 m) in the southeastern part of SRS. There is some controversy over the age of the Clinchfield Formation and, therefore, also of the Utley Limestone Member.
Paleontologically, it could be late Claibornian in age and correlative with the Gosport Sand of southwestern Alabama. Like the Gosport, the Clinchfield Formation is variable in thickness over short distances in kaolin mines in central Georgia due, apparently, to filling of topographic lows on the top of the Oconee Group (Huddlestun and Hetrick, 1986) during the Barnwell transgression.
In most places, the upper contact of the Clinchfield with the overlying Tivola Limestone (or Dry Branch Formation) appears to be conformable, gradational and horizontal in most kaolin mines in central Georgia (in contrast to a basal irregular contact).
of the Barnwell Formation of Shearer, 1917; or as undivided Barnwell Formation of Veatch and Stephenson, 1911). As defined by Huddlestun and Hetrick (1979, 19861, the Dry Branch Formation consists of three formal members, each one of which constitutes the entire Dry Branch section in the areas where they are typically developed.
These are the Twiggs Clay Member, Irwinton Sand Member and Griffins Landing Member. Where these particular lithofacies are not well-developed, the Dry Branch Formation may be composed of any two or three of the member lithofacies.
In Burke County, all three lithofacies are present, but only the Irwinton Sand and Griffins Landing can be considered as members. A Twiggs-type clay occurs as thin beds or lenses within Irwinton Sand Member and Griffins Landing Member. me Locality The name Dry Branch is taken from the community of Dry Branch, located on U.S. Hwy. 80 on the Bibb-Twiggs County line. The type locality of the Dry Branch Formation is in Twiggs County, along an abandoned kaolin haul road at the entrance to an abandoned kaolin mine, 0.6 miles (1 km) from the junction of the haul road and U.S. Hwy. 80 at the highway bridge over the Seaboard Coast Line Railroad, 2.3 miles (3.7 km) south of Dry Branch. The section of Barnwell exposed beneath the Tobacco Road Sand is the type section, unit-stratotype (holostratotype) of the Dry Branch Formation (Huddlestun and Hetrick, 1986). The section of Dry Branch exposed in the pit consists of the Irwinton Sand Member with beds or lenses of Twiggs-type clay. Lithology Dry Branch Formation Definition The Dry Branch Formation was named by Huddlestun and Hetrick (1979, 1986) for a body of deposits that had been previously called members of the Barnwell Formation (Irwinton Sand Member of the Barnwell Formation of LaMoreaux, 1946a, 1946b; Twiggs Clay Member The Dry Branch Formation locally consists of three distinct but interfingering lithofacies:
1.) a marine smectitic clay lithofacies (Twiggs Clay); 2.) a prominently stratified sand and sand-clay lithofacies (Irwinton Sand);
and 3.) a crudely bedded, thick-bedded and massive, calcareous, fossiliferous, argillaceous sand lithofacies (Griffins Landing Member). In many areas of Georgia, however, a fine distinction the McBean Member and undifferentiated Lisbon Formation in northern Burke County, and dis conformably overlies the Blue Bluff Member in central and southern Burke County.The Utley in turn is overlain with apparent conformity by the Dry Branch Formation, but the contact is generally sharp.In northern Burke County, Utley Limestone ranges in thickness from 0 feet (where absent)to 13 feet (4 m)at the type locality.Its average thickness in northern Burke County (based on 8 sites)is approximately 7 feet (2 m).The Utley limestone is systematically thicker in southern Burke County where it ranges from 10 feet (3 m)in core VG-4 to 34 feet (10 m)in core VG-8.Fallaw and Price (1992, 1995)reported 30 feet (9 m)in the southeastern part of SRS.Age There is some controversy over the age of the Clinchfield Formationand,therefore, also of the Utley Limestone Member.Paleontologically, it could be late Claibornian in age and correlative with the Gosport Sand of sopthwestern Alabama.Like the Gosport, the Clinchfield Formation is variable in thickness over short distances in kaolin mines in central Georgia due, apparently, to filling of topographic lows on the top of the Oconee Group (Huddlestun and Hetrick, 1986)during the Barnwell transgression.
In most places, the upper contact of the Clinchfield with the overlying Tivola Limestone (or Dry Branch Formation) appears to be conformable, gradational and horizontal in most kaolin mines in central Georgia (in contrast to a basal irregular contact).Dry Branch Formation Definition The Dry Branch Formation was named by Huddlestun and Hetrick (1979, 1986)for a body of deposits that had been previously called members of the Barnwell Formation UIWinton Sand Member of the Barnwell Formation of LaMoreaux, 1946a, 1946b;Twiggs Clay Member 68 of the Barnwell Formation of Shearer, 1917;or as undivided Barnwell Formation of Veatch and Stephenson, 1911).As defined by Huddlestun and Hetrick (1979, 1986), the Dry Branch Formation consists of three formal members, each one of which constitutes the entire Dry Branch section in the areas where they are typically developed.
These are the Twiggs Clay Member, IIWinton Sand Member and Griffins Landing Member.Where these particular lithofacies are not well-developed, the Dry Branch Formation may be composed of any two or three of the member lithofacies.
In Burke County, all three lithofacies are present, but only the IIWinton Sand and Griffins Landing can be considered as members.A Twiggs-type clay occurs as thin beds or lenses within IIWinton Sand Member and Griffins Landing Member.Type Locality The name Dry Branch is taken from the community of Dry Branch, located on U.S.Hwy.80 on the Bibb-Twiggs County line.The type locality of the Dry Branch Formation is in Twiggs County, along an abandoned kaolin haul road at the entrance to an abandoned kaolin mine, 0.6 miles (1 km)from the junction of the haul road and U.S.Hwy.80 at the highway bridge over the Seaboard Coast Line Railroad, 2.3 miles (3.7 km)south of Dry Branch.The section of Barnwell exposed beneath the Tobacco Road Sand is the type section, unit-stratotype (holostratotype) of the Dry Branch Formation (Huddlestun and Hetrick, 1986).The section of Dry Branch exposed in the pit consists of the IIWinton Sand Member with beds or lenses of Twiggs-type clay.Lithology The Dry Branch Formation locally consists of three distinct but interfingering lithofacies:
1.)a marine smectitic clay lithofacies (Twiggs Clay);2.)a prominently stratified sand and sand-clay lithofacies (lIWinton Sand);and 3.)a crudely bedded, thick-bedded and massive, calcareous, fossiliferous, argillaceous sand lithofacies (Griffins Landing Member).In many areas of Georgia, however, a fine distinction between the lithofacies, due to complex interfingering and intergradation, is not possible.
In those areas, for mapping purposes and purposes of discussion, it is best to distinguish only the formation and to recognize the facies subdivisions as informal lithofacies, lithosomes or lithostromes. Stratigraphic Relationships In northern Burke County, the Irwinton Sand constitutes most of the Dry Branch Formation and, in Richmond County immediately to the north, the Irwinton constitutes all of the Dry Branch.
In northernmost Burke County, the Gfins Landing Member occurs at the base of the formation and thickens irregularly southward at the expense of the overlying Irwinton Sand. In southern Burke County, the Dry Branch Formation consists mostly of the Gfins Landing Member with Irwinton Sand occurring only at the top of the formation.
Farther south in northern Screven County, the Gfins Landing Member constitutes all of the Dry Branch Formation.
The Dry Branch Formation overlies, with apparent conformity, the Utley Limestone Member of the Clinchfield Sand. Within the Dry Branch Formation in central and southern Burke County, the Gfins Landing appears to grade both upward and laterally into the Irwinton Sand suggesting that, for a brief time, both members were being deposited contemporaneously.
During the later phase of deposition of the Dry Branch Formation, the Irwinton Sand was deposited across the entire eastern part of Burke County. In addition, the contact between Griffins Landing Member and Irwinton Sand Member is obscured by deep weathering of the Irwinton sand and the upper part of the Griffins Landing. However, in most cores, there is a clear distinction between weathered Irwinton Sand and weathered Griffins Landing. Bedding characteristics of the two members are different and leaching of the calcareous Griffins Landing commonly results in precipitation of wad on bedding surfaces, joints, or fractures.
Because the Dry Branch Formation is deeply dissected in Burke County, its apparent thickness is quite variable, being absent where stream erosion has completely removed the formation. However, the variation in original thickness of the Dry Branch Formation can be determined where the overlying Tobacco Road Sand is still present. Only three cores in eastern Burke County were taken at sufficiently high elevations for the Tobacco Road to be identified.
These three cores are GGS McBean, TR92-2, and VG-6 (Figure 2, Table 1). The Dry Branch is 67 feet (20 m) in the GGS McBean core near McBean Creek, 101 feet (30.8 m) in the TR92-2 core in central Burke County near Hancock Landing, and 163 feet (49.7 m) in the VG-6 core east of Girard in southern Burke County. These three thicknesses suggest that the Dry Branch Formation thickens at the rate of approximately 4 feetlmile (1.2 m/km) to the southeast.
The depositional environment of the Dry Branch Formation was shallow to very shallow water, inner neritic, marine. The abundance of sand, undulatory bedding and cross bedding, and the presence of Crassostrea gigantissima suggests a near-shore environment near an influx of fresh water as opposed to normal, open-ocean water. The presence of Twiggs clay and Gfins Landing interfingering strongly suggests a near-shore facies mosaic that includes bays and lagoons, beaches, tidal inlets, and oyster reefs. Water depth during deposition of the Irwinton Sand must have been very shallow subtidal whereas that of the Griffins Landing was only slightly deeper, such that open-ocean, planktonic foraminifera could survive in southern Burke County. However, the presence of Crassostrea gigantissima bioherms suggest that the sea water was also sligh'dy brackish at times. The Dry Branch Formation is Late Eocene, early Jacksonian in age (Huddlestun and Hetrick, 1986). between the lithofacies, due to complex interfingering and intergradation, is not possible.In those areas, for mapping purposes and purposes of discussion, it is best to distinguish only the formation and to recognize the facies subdivisions as informal lithofacies, lithosomes or lithostromes.
Stratigraphic Relationships In northern Burke County, the Irwinton Sand constitutes most of the Dry Branch Formation and, in Richmond County immediately to the north, the Irwinton constitutes' all of the Dry Branch.In northernmost Burke County, the Griffins Landing Member occurs at the base of the formation and thickens irregularly southward at the expense of the overlying Irwinton Sand.In southern Burke County, the Dry Branch Formation consists mostly of the Griffins Landing Member with Irwinton Sand occurring only at the top of the formation.
Farther south in northern Screven County, the Griffins Landing Member constitutes all of the Dry Branch Formation.
The Dry Branch Formation overlies, with apparent conformity, the Utley Limestone Member of the Clinchfield Sand.Within the Dry Branch Formation in central and southern Burke County, the Griffins Landing appears to grade both upward and laterally into the Irwinton Sand suggesting that, for a brief time, both members were being deposited contemporaneously.
During the later phase of deposition of the Dry Branch Formation, the Irwinton Sand was deposited across the entire eastern part of Burke County.In addition, the contact between Griffins Landing Member and Irwinton Sand Member is obscured by deep weathering of the Irwinton sand and the upper part of the Griffins Landing.However, in most cores, there is a clear distinction between weathered Irwinton Sand and weathered Griffins Landing.Bedding characteristics of the two members are different and leaching of the calcareous Griffins Landing commonly results in precipitation of wad on bedding surfaces, joints, or fractures.
69 Because the Dry Branch Formation is deeply dissected in Burke County, its apparent thickness is quite variable, being absent where stream erosion has completely removed the formation.
However, the variation in original thickness of the Dry Branch Formation can be determined where the overlying Tobacco Road Sand is still present.Only three cores in eastern Burke County were taken at sufficiently high elevations for the Tobacco Road to be identified.
These three cores are GGS McBean, TR92-2, and VG-6 (Figure 2, Table 1).The Dry Branch is 67 feet (20 m)in the GGS McBean core near McBean Creek, 101 feet (30.8 m)in the TR92-2 core in central Burke County near Hancock Landing, and 163 feet (49.7 m)in the VG-6 core east of Girard in southern Burke County.These three thicknesses suggest that the Dry Branch Formation thickens at the rate of approximately 4 feet/mile (1.2 mjkm)to the southeast.
The depositional environment of the Dry Branch Formation was shallow to very shallow water, inner neritic, marine.The abundance of sand, undulatory bedding and cross bedding, and the presence of Crassostrea gigantissima suggests a near-shore environment near an influx of fresh water as opposed to normal, open-ocean water.The presence of Twiggs clay and Griffins Landing interfingering strongly suggests a near-shore facies mosaic that includes bays and lagoons, beaches, tidal inlets, and oyster reefs.Water depth during deposition of the Irwinton Sand must have been very shallow subtidal whereas that of the Griffins Landing was only slightly deeper, such that open-ocean, planktonic foraminifera could survive in southern Burke County.However, the presence of Crassostrea gigantissima bioherms suggest that the sea water was also slighily brackish at times.Age The Dry Branch Formation is Late Eocene, early Jacksonian in age (Huddlestun and Hetrick, 1986).
Twiggs Clay Lithofacies Type Locality Lithology Clay beds within the Dry Branch Formation essentially have the same lithology as the eastern facies of the Twiggs Clay Member of the Dry Branch Formation (Huddlestun and Hetrick, 19861, characterized by a paucity of calcite and glauconite and the presence of opal- cristobalite.
140 opal-cristobalite has been reported from the Twiggs-type clay beds in Burke County, however. In general, the Twiggs-type clay is a yellowish gray to light olive gray, dense, silty clay with hackly, blocky, shaley, subconchoidal to conchoidal fracture. Where the clay is almost pure and unaltered by weathering, it commonly displays a combination of blocky and conchoidal fracture. Where it is weathered, its fracture is pronouncedly hackly. Stratigraphic Relationships The Twiggs Clay lithology is present in Burke County as clay lenses scattered throughout the Irwinton Sand and GrBns Landing, most commonly at or near the base of either member. Where present, the thickness usually ranges from
.3 feet (in core VG-3) to 22 feet (in core VG-5).
In core VG-5, the Twiggs Clay unit overlies the GrBns Landing Member. Griffins Landing Member Definition Huddlestun and Hetrick (1986) na- -ed the GrBns Landing Member of the Dry Branch Formation for beds exposed at GrBns Landing on the Savannah River in Burke County, Georgia. The GrBns Landing Member is relatively well exposed in the Savannah River area, both in Burke County, Georgia, and Barnwell County, South Carolina.
The GrBns Landing Member is distinguished from the rest of the Barnwell Group in being typically calcareous, micro- or macrofossiliferous, thick- to massive-bedded, and devoid of sedimentary or biogenic structures. The type locality of the GrBns Landing Member of the Dry Branch is at Grithns Landing on the Savannah River, 1.4 miles (2.3 km) north of the junction of Grifhs Landing Road and River Road, and 5.2 air-miles (8.4 km) north of Girard in Burke County. The section exposed at GrBns Landing is the type section, or unit-stratotype of the GrBns Landing Member. Neither lower nor upper boundaries are exposed at the landing but Price (personal communication, 1993) identified the top of the Utley Limestone several hundred feet south of the landing. Lithology In general, the GrBns Landing Member is a fairly well sorted, massive to vaguely and rudely bedded, calcareous sand. In the updip areas of Burke County, thin limestone beds, clay beds or lenses, local oyster (Crassostrea gigantissirnu) beds and bioherms, and chert and silica-cemented sandstone (as at Stony Bluff Landing) are common. Subordinate lithic components include smectite clay, calcite, shells, zeolite, chert, mica, glauconite and wad. In many outcrops and cores, the GrBns Landing Member shows few primary sedimentary or biogenic structures, especially in the downdip, shallow subsurface where it consists of a thick-bedded, uniformly structureless, somewhat argillaceous, calcareous, microfossiliferous, well-sorted, medium-grained sand. Vague stratification can be seen in outcrop on etched surfaces, as at GrBns Landing, and in some cores from the shallow subsurface.
Stratigraphic Relationships The GrBns Landing Member at this time appears to be restricted to the Upper Eocene outcrop belt in the vicinity of the Savannah River. Other than minor lenses of GrBns Landing lithology in the Dry Branch Formation in central Georgia, we know of no certain occurrences of the GrBns Landing Twiggs Clay Lithofacies Lithology Clay beds within the Dry Branch Formation essentially have the same lithology as the eastern facies of the Twiggs Clay Member of the Dry Branch Formation (Huddlestun and Hetrick, 1986), characterized by a paucity of calcite and glauconite and the presence ofcristobalite.
Ifo opal-cristobalite has been reported from the Twiggs-type clay beds in Burke County, however.In general, the Twiggs-type clay is a yellowish gray to light olive gray, dense, silty clay with hack1y, blocky, shaley, subconchoidal to conchoidal fracture.Where the clay is almost pure and unaltered by weathering, it commonly displays a combination of blocky and conchoidal fracture.Where it is weathered, its fracture is pronouncedly hack1y.Stratigraphic Relationships The Twiggs Clay lithology is present in Burke County as clay lenses scattered throughout the Irwinton Sand and Griffins Landing, most commonly at or near the base of either member.Where present, the thickness usually ranges from.3 feet (in core VG-3)to 22 feet (in core VG-5).In core VG-5, the Twiggs Clay unit overlies the Griffins Landing Member.Griffins Landing Member Definition Huddlestun and Hetrick (1986)na-_ed the Griffins Landing Member of the Dry Branch Formation for beds exposed at Griffins Landing on the Savannah River in Burke County, Georgia.The Griffins Landing Member is relatively well exposed in the Savannah River area, both in Burke County, Georgia, and Barnwell County, South Carolina.The Griffins Landing Member is distinguished from the rest of the Barnwell Group in being typically calcareous, micro-or macrofossiliferous, thick-to massive-bedded, and devoid of sedimentary or biogenic structures.
70 Type Locality The type locality of the Griffins Landing Member of the Dry Branch is at Griffins Landing on the Savannah River, 1.4 miles (2.3 km)north of the junction of Griffins Landing Road and River Road, and 5.2 air-miles (8.4 km)north of Girard in Burke County.The section exposed at Griffins Landing is the type section, or unit-stratotype of the Griffins Landing Member.Neither lower nor upper boundaries are exposed at the landing but Price (personal communication, 1993)identified the top of the Utley Limestone several hundred feet south of the landing.Lithology In general, the Griffins Landing Member is a fairly well sorted, massive to vaguely and rudely bedded, calcareous sand.In the updip areas of Burke County, thin limestone beds, clay beds or lenses, local oyster<Crassostrea gigantissima) beds and bioherms, and chert and silica-cemented sandstone (as at Stony Bluff Landing)are common.Subordinate lithic components include smectite clay, calcite, shells, zeolite, chert, mica, glauconite and wad.In many outcrops and cores, the Griffins Landing Member shows few primary sedimentary or biogenic structures, especially in the downdip, shallow subsurface where it consists of a thick-bedded, uniformly structureless, somewhat argillaceous, calcareous, microfossiliferous, well-sorted, medium-grained sand.Vague stratification can be seen in outcrop on etched surfaces, as at Griffins Landing,andin some cores from the shallow subsurface.
Stratigraphic Relationships The Griffins Landing Member at this time appears to be restricted to the Upper Eocene outcrop belt in the vicinity of the Savannah River.Other than minor lenses of Griffins Landing lithology in the Dry Branch Formation in central Georgia, we know of no certain occurrences of the Griffins Landing Member west of Burke County in Georgia (see Huddlestun and Hetrick, 1986). The GSns Landing Member is in the lower part of the Dry Branch Formation where it grades laterally and vertically into the Irwinton Sand (Huddlestun and Hetrick, 1986). The Griffins Landing is absent farther north in Richmond County where the Irwinton Sand Member directly overlies either the Albion Member of the Clinchfield Formation or the underlying Oconee Group. Farther south in Screven County, Georgia, the Griffins Landing Member composes the entire Dry Branch Formation.
The GSns Landing Member thickens southeastward in Burke County. In northern Burke County, its thickness is variable, ranging from 0 feet where it is locally absent due to non- deposition, to as much 96.5 feet in the core TR92-5. Average thickness of the GSns Landing Member in northern Burke County is 34 feet (11 m). Where the GSns Landing Member is absent, either the Irwinton Sand directly overlies the McBean Member of the Lisbon Formation or undifferentiated Dry Branch Formation directly overlies the Utley Limestone. In southern Burke County, where the Gfins Landing Member is consistently present, thickness ranges from 36 feet (12 m) in core VG-3 to 123 feet (40 m) in core VG-2. Average thickness of the Gfins Landing Member in southern Burke County is approximately 74 feet (23 m). The environment of deposition of the Griffins Landing Member was shallow, inner continental shelf. The common occurrence of Crassostrea suggests that the salinity of the sea water may have been slightly brackish or variable.
The age of the Gfins Landing Member of the Dry Branch Formation is Late Eocene, early Jacksonian (Huddlestun and Hetrick (1986). Irwinton Sand Member Definition The Irwinton Sand was named by LaMoreaux (194% 194613) for a soft, commonly loose and incoherent, fine to medium, stratified, noncalcareous sand that contains thin beds, lenses, laminae, or clasts of Twiggs-type clay (see Huddlestun and Hetrick, 1986). Type Locality The name Irwinton is derived from the town of Irwinton in Wilkinson County, Georgia. The type locality of the Irwinton Sand is in gullies, now overgrown, on the west side of U.S. Hwy. 441 (Ga. Hwy. 29), 0.3 mile (0.5 km) south of the courthouse in Irwinton. The type section, unit-stratotype (holostratotype), of the Irwinton Sand is the section of sand overlying the Twiggs Clay in the gullies at Irwinton.
When LaMoreaux (194% 194613) described the type section, there was 44 feet (13 m)' of Irwinton Sand overlying 20+ feet (6.1 + m) of Twiggs Clay and underlying about 12 feet (3.7 m) of weathered clay that LaMoreaux (1946a, 194613) described as colluvium but Huddlestun and Hetrick (1986, p. 40) considered to be a deeply weathered bed or lens of Twiggs-clay lithofacies.
Lithology The Irwinton Sand typically consists of fine- to medium- grained, well-sorted, almost pure quartz sand that shows well-developed small-scale, horizontally bedded, undulatory bedded, and cross-bedded sand. Accessory lithic components include mainly smectitic clay and minor amounts of illite and kaolinite. Some weathered beds of clay in the Irwinton are composed entirely of kaolin, apparently altered from smectite.
All Irwinton clay beds (smectite) we know of are of Twiggs Clay-type lithology.
Other accessary minerals in the Irwinton Sand include chert, locally conspicuous dark minerals, and very minor mica. Sand in the Irwinton is fine- to medium- grained and well-sorted. Coarser beds are more Member west of Burke County in Georgia (see Huddlestun and Hetrick, 1986).The Griffins Landing Member is in the lower part of the Dry Branch Formation where it grades laterally and vertically into the Irwinton Sand (Huddlestun and Hetrick, 1986).The Griffins Landing is absent farther north in Richmond County where the Irwinton Sand Member directly overlies either the Albion Member of the Clinchfield Formation or the underlying Oconee Group.Farther south in Screven County, Georgia, the Griffins Landing Member composes the entire Dry Branch Formation.
The Griffins Landing Member thickens southeastward in Burke County.In northern Burke County, its thickness is variable, ranging from 0 feet where it is locally absent due todeposition, to as much 96.5 feet in the core TR92-5.Average thickness of the Griffins Landing Member in northern Burke County is 34 feet (11 m).Where the Griffins Landing Member is absent, either the Irwinton Sand directly overlies the McBean Member of the Lisbon Formation or undifferentiated Dry Branch Formation directly overlies the Utley Limestone.
In southern Burke County, where the Griffins Landing Member is consistently present, thickness ranges from 36 feet (12 m)in core VG-3 to 123 feet (40 m)in core VG-2.Average thickness of the Griffins Landing Member in southern Burke County is approximately 74 feet (23 m).The environment of deposition of the Griffins Landing Member was shallow, inner continental shelf.The common occurrence of Crassostrea suggests that the salinity of the sea watermayhave been slightly brackish or variable.Age The age of the Griffins Landing Member of the Dry Branch Formation is Late Eocene, early Jacksonian (Huddlestun and Hetrick (1986).71 Irwinton Sand Member Definition The Irwinton Sand was named by LaMoreaux (1946a, 1946b)for a soft, commonly loose and incoherent, fine to medium, stratified, noncalcareous sand that contains thin beds, lenses, laminae, or clasts of Twiggs-type clay (see Huddlestun and Hetrick, 1986).Type Locality The name Irwinton is derived from the town of Irwinton in Wilkinson County, Georgia.The type locality of the Irwinton Sand is in gullies, now overgrown, on the west side of U.S.Hwy.441 (Ga.Hwy.29), 0.3 mile (0.5 km)south of the courthouse in Irwinton.The type section, unit-stratotype (holostratotype), of the Irwinton Sand is the section of sand overlying the Twiggs Clay in the gullies at Irwinton.When LaMoreaux (1946a, 1946b)described the type section, there was 44 feet (13 mr of Irwinton Sand overlying 20+feet (6.1+m)of Twiggs Clay and underlying about 12 feet (3.7 m)of weathered clay that LaMoreaux (1946a, 1946b)described as colluvium but Huddlestun and Hetrick (1986, p.40)considered to be a deeply weathered bed or lens of Twiggs-clay lithofacies.
Lithology The Irwinton Sand typically consists of fine-to medium-grained, well-sorted, almost pure quartz sand that shows well-developed small-scale, horizontally bedded, undulatory bedded, and cross-bedded sand.Accessory lithic components include mainly smectitic clay and minor amounts of illite and kaolinite.
Some weathered beds of clay in the Irwinton are composed entirely of kaolin, apparently altered from smectite.All Irwinton clay beds (smectite) we know of are of Twiggs Clay-type lithology.
Other accessary minerals in the Irwinton Sand include chert, locally conspicuous dark minerals, and very minor mica.Sand in the Irwinton is fine-tograined and well-sorted.
Coarser beds are more poorly sorted. Typically, the Irwinton Sand is soft and unconsolidated, in some places even incoherent.
Therefore, the Irwinton is a "slope- former". There are some poorly sorted sand beds within the Irwinton, especially in the far updip areas. Some sections are dominated by medium to coarse, rarely pebbly, moderately well to poorly sorted sand. Most exposures of the Irwinton Sand contain some beds, lenses, and laminae of disrupted clay clasts of Twiggs-type smeditic clay. In general, all the clay beds in the Irwinton probably are lenses, but the thicker clay beds are more areally extensive than the thin beds, and the clay laminae are especially discontinuous.
The clay beds and lenses within the Irwinton Sand produce locally perched water tables. Stratigraphic Relationships The Irwinton Sand Member of the Dry Branch is present throughout Burke County. It is thickest in the northern part of the county, especially in the study area where its thickness can be as much as 80 feet (24 m). In some exposures, the Irwinton/Tobacco Road contact appears to be slightly gradational.
In other exposures, it appears that the basal flat pebble bed of the Tobacco Road disconformably overlies the Irwinton Sand.
The Irwinton Sand gradationally overlies the Griffins Landing Member. In addition, the lower part of the Irwinton appears to grade laterally into the upper part of the Griffins Landing. The vertical gradation between the Irwinton and Griffins Landing is rarely seen in outcrop and, because of deep weathering and poor core recovery across the Irwinton-Griffins Landing boundary, it is rarely seen in cores. Where there is poor recovery in cores, we arbitrarily place the Irwinton-Griffins Landing contact near the lowest occurrence of prominent bedding, and the highest occurrence of wad (hydrated MnO,), chert, or calcium carbonate.
The Irwinton is most easily identilied where the sand is conspicuously and thinly stratilied and noncal~a~eous.
The age of the Irwinton Sand Member of the Dry Branch Formation is Late Eocene, early Jacksonian (Huddlestun and Hetrick, 1986). Tobacco Road Sand Definition The Tobacco Road Sand was named by Huddlestun and Hetrick (1978) for upper Jacksonian deposits that previously had been called the upper sand member of the Barnwell Formation by LaMoreaux (19464 1946b). Type Locality The name Tobacco Road was taken from the Tobacco Road highway in southern Richmond County.
The type locality of the Tobacco Road Sand is located on the east side of Morgan Road, 0.3 miles (0.6 km) north of the intersection of Morgan Road and Tobacco Road, Richmond County, Georgia.
The type section, or unit-stratotype (holostratotype) of the Tobacco Road Sand is that section of the formation exposed at the type locality (Huddlestun and Hetrick, 1978, 1979, 1986).
Lithology Tobacco Road is predominantly a sand, all other lithic components (clay minerals, chert, calcite, limestone, mica, glauconite, dark minerals and wad) are only locally significant.
The most characteristic lithology of the Tobacco Road Sand is a burrowed and bioturbated, massive-bedded, moderately poorly sorted, medium- to coarse-grained, pebbly, weathered sand. This particular lithofacies of the formation is more prevalent in the downdip areas of the outcrop belt such as Burke County. Although most exposures show little or no bedding, vague, rude bedding and disrupted thin bedding are probably the norm for the formation as a whole. For example, at Stop 3 of the 1992 Carolina Geological field trip (Fallaw and Price, 1992), most of the 35 feet (11 m) of Tobacco Road Sand section consists of crudely bedded, very broadly poorly sorted.Typically, the Irwinton Sand is soft and unconsolidated, in some places even incoherent.
Therefore, the Irwinton is aformer".There are some poorly sorted sand beds within the Irwinton, especially in the far updip areas.Some sections are dominated by medium to coarse, rarely pebbly, moderately well to poorly sorted sand.Most exposures of the Irwinton Sand contain some beds, lenses, and laminae of disrupted clay clasts of Twiggs-type smectitic clay.In general, all the clay beds in the Irwinton probably are lenses, but the thicker clay beds are more areally extensive than the thin beds, and the clay laminae are especially discontinuous.
The clay beds and lenses within the Irwinton Sand produce locally perched water tables.Stratigraphic Relationships The Irwinton Sand Member of the Dry Branch is present throughout Burke County.It is thickest in the northern part of the county, especially in the study area where its thickness can be as much as 80 feet (24 m).In some exposures, the Irwinton/Tobacco Road contact appears to be slightly gradational.
In other exposures, it appears that the basal flat pebble bed of the Tobacco Road disconformably overlies the Irwinton Sand.The Irwinton Sand gradationally overlies the Griffins Landing Member.In addition, the lower part of the Irwinton appears to grade laterally into the upper part of the Griffins Landing.The vertical gradation between the Irwinton and Griffins Landing is rarely seen in outcrop and, because of deep weathering and poor core recovery across the Irwinton-Griffins Landing boundary, it is rarely seen in cores.Where there is poor recovery in cores, we arbitrarily place the Irwinton-Griffins Landing contact near the lowest occurrence of prominent bedding, and.the highest occurrence of wad (hydrated Mn0 2), chert, or calcium carbonate.
The Irwinton is most easily identified where the sand is conspicuously and thinly stratified and noncaleateous.
72 Age The age of the Irwinton Sand Member of the Dry Branch Formation is Late Eocene, early Jacksonian (Huddlestun and Hetrick, 1986).Tobacco Road Sand Definition The Tobacco Road Sand was named by Huddlestun and Hetrick (1978)for upper Jacksonian deposits that previously had been called the upper sand member of the Barnwell Formation by LaMoreaux (1946a, 1946b).Type Locality The name Tobacco Road was taken from the Tobacco Road highway in southern Richmond County.The type locality of the Tobacco Road Sand is located on the east side of Morgan Road, 0.3 miles (0.6 km)north of the intersection of Morgan Road and Tobacco Road, Richmond County, Georgia.The type section, or unit-stratotype (holostratotype) of the Tobacco Road Sand is that section of the formation exposed at the type locality (Huddlestun and Hetrick, 1978, 1979, 1986).Lithology Tobacco Road is predominantly a sand, all other lithic components (clay minerals, chert, calcite, limestone, mica, glauconite, dark minerals and wad)are only locally significant.
The most characteristic lithology of the Tobacco Road Sand is a burrowed and bioturbated, massive-bedded, moderately poorly sorted, medium-to coarse-grained, pebbly, weathered sand.This particular lithofacies of the formation is more prevalent in the downdip areas of the outcrop belt such as Burke County.Although most exposures show little or no bedding, vague, rude bedding and disrupted thin bedding are probably the norm for the formation as a whole.For example, at Stop 3 of the 1992 Carolina Geological field trip (Fallaw and Price, 1992), most of the 35 feet (11 m)of Tobacco Road Sand section consists of crudely bedded, very broadly cross-bedded to horizontally bedded sand with massive-bedded,variably sorted, medium-grained sand in the lower part. The characteristic burrowed and bioturbated sand occurs only in the upper 6 feet (2 m) of the formation.
In most places, however, crude bedding can be observed only on close inspection. A zone of flat pebbles occurs at the base of the Tobacco Road Sand in many places in central and eastern Georgia. Although discontinuous, this bed is very useful for locating the base of the Tobacco Road and the top of the underlying Dry Branch Formation (Huddlestun and Hetrick, 1978,1986).
The flat pebble bed is common in northern Burke County but becomes less common southward as average siliciclastic grain-size decreases.
Where the flat pebble bed is absent, chert, or coarse, granular sand is commonly present at the base of the formation, especially where the formation is unusually fine grained and consists mainly of fine- to medium- grained, well-sorted sand. Stratigraphic Relationships The Tobacco Road Sand occurs at the top of upland, interfluve sections in the study area. The upper part of the formation generally is deeply weathered and highly pigmented (most commonly moderate reddish brown), although in some exposed sections or cores the pigmentation is more variegated. Deep weathering of the Tobacco Road Sand has caused it to become case-hardened and resistant to both chemical and physical weathering.
Thus, it is a ledge- forming unit, and commonly is eroded by undercutting of the soft sands of the Dry Branch Formation.
The Irwinton Sand Member of the Dry Branch Formation underlies the Tobacco Road Sand paraconformably or with abrupt contact. In the study area in northern Burke County, the Tobacco Road Sand occurs at the top of the stratigraphic section. Elsewhere in Burke County, the Miocene Altamaha Formation overlies the Tobacco Road disconformably.
Based on the local abundance of the ghost shrimp burrow Ophiomrpha nodosa, the presence of the sand dollar Periarchus quinquefarius, chert with molds and casts of mollusks with Periarchus quinquefarius, flat pebbles, and the local occurrence of prominent undulatory bedding and cross bedding, the environment of deposition of the Tobacco Road is inferred to be coastal marine, beach, to back- barrier (Huddlestun and Hetrick, 1978, 1986). The Tobacco Road Sand is Latest Eocene, late Jacksonian in age (Huddlestun and Hetrick, 1978, 1986).
REFERENCES CITED Aadland, R. K.; Thayer, P, A.; and Smits, A. D., 1992 Hydrostratigraphy of the Savannah River Site region, South Carolina and Georgia, b- Fallaw, W., and Price, V., (eds.), Geological investigations of the central Savannah River area, South Carolina and Georgia; South Carolina Geological Society (SCGS) Field Trip Guidebook 1992, p. CGS-92-B-X-1-6. American Commission on Stratigraphic Nomenclature, 1961 Code of Stratigraphic Nomenclature; American Assoc. Petroleum Geologists (AAPG) Bulletin, vol. 45, no. 5, p. 645-665. American Commission on Stratigraphic Nomenclature, 1970 Code of Stratigraphic Nomenclature (2nd printing);
AAPG, Tulsa, Okla, 22 p. Bandy, 0. L., 1949 Eocene and Oligocene foraminifera from Little Stave Creek, Clarke County, Alabama; Bulletin American Paleontology, vol. 32, no. 131, p. 210. Bechtel Corporation, 1982 Studies of the postulated Millett fault; Bechtel Corporation, San Francisco, vol. 1 Berggren, W. A., 1972 A Cenozoic time-scale-some implications for regional geology and paleobiology; Lethaia, vol. 5, p. 195-215. Blow, W. H., 1969 Late middle Eocene to Recent planktonic foraminiferal biostratigraphy, cross-bedded to horizontally bedded sand with massive-bedded, variably sorted, medium-grained sand in the lower part.The characteristic burrowed and bioturbated sand occurs only in the upper 6 feet (2 m)of the formation.
In most places, however, crude bedding can be observed only on close inspection.
A zone of flat pebbles occurs at the base of the Tobacco Road Sand in many places in central and eastern Georgia.Although discontinuous, this bed is very useful for locating the base of the Tobacco Road and the top of the underlying Dry Branch Formation (Huddlestun and Hetrick,1978,1986).
The flat pebble bed is common in northern Burke County but becomes less common southward as average siliciclastic grain-size decreases.
Where the flat pebble bed is absent, chert, or coarse, granular sand is commonly present at the base of the formation, especially where the formation is unusually fine grained and consists mainly of fine-tograined, well-sorted sand.Stratigraphic Relationships The Tobacco Road Sand occurs at the top of upland, intertluve sections in the study area.The upper part of the formation generally is deeply weathered and highly pigmented (most commonly moderate reddish brown), although in some exposed sections or cores the pigmentation is more variegated.
Deep weathering of the Tobacco Road Sand has caused it to become case-hardened and resistant to both chemical and physical weathering.
Thus, it is aforming unit, and commonly is eroded by undercutting of the soft sands of the Dry Branch Formation.
The Irwinton Sand Member of the Dry Branch Formation underlies the Tobacco Road Sand paraconformably or with abrupt contact.In the study area in northern Burke County, the Tobacco Road Sand occurs at the top of the stratigraphic section.Elsewhere in Burke County, the Miocene Altamaha Formation overlies the Tobacco Road disconformably.
Based on the local abundance of the ghost shrimp burrow Ophiomorpha nodosa, the presence of the sand dollar Periarchus quinquefarius, chert with molds and casts of 73 mollusks with Periarchus quinquefarius, flat pebbles, and the local occurrence of prominent undulatory bedding and cross bedding, the environment of deposition of the Tobacco Road is inferred to be coastal marine, beach, tobarrier (Huddlestun and Hetrick, 1978, 1986).Age The Tobacco Road Sand is Latest Eocene, late Jacksonian in age (Huddlestun and Hetrick, 1978, 1986).REFERENCES CITED Aadland, R.K.;Thayer, P, A;and Smits, A D., 1992 Hydrostratigraphy of the Savannah River Site region, South Carolina and Georgia,Fallaw, W., and Price, V., (eds.), Geological investigations of the central Savannah River area, South Carolina and Georgia;South Carolina Geological Society (SCGS)Field Trip Guidebook 1992, p.CGS-92-B-X-1-6.
American Commission on Stratigraphic Nomenclature, 1961 Code of Stratigraphic Nomenclature; American Assoc.Petroleum Geologists (AAPG)Bulletin, vol.45, no.5, p.645-665.American Commission on Stratigraphic Nomenclature, 1970 Code of Stratigraphic Nomenclature (2nd printing);
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A., 1992 Lower Eocene strata at the Savannah River Site, South Carolina; h- Zullo, V. A.; Harris, W. B.; and Price, V. (eds.), Savannah River Region: Transition Between the Gulf and Atlantic Coastal Plains; Proceedings of the Second Bald Head Island Conference on Coastal Plains Geology, University of North Carolina and U. S. DOE, p. 52-53. Prowell, D. C., Edwards, L. E., and Frederiksen, N. O., 1985a The Ellenton Formation in South Carolina-a revised age designation from Cretaceous to Paleocene; USGS Bulletin 1605-A, p. A63-A69. Prowell, D. C.; Christopher, R. A.; Edwards. E.; Bybell, L. M.; and Gill, H. E., 198523 Geologic section of the updip Coastal Plain from central Georgia to western South Carolina; USGS Miscellaneous Field Studies Map, MF-1737, 10 P . Reinhardt, J., and Gibson, T. G., 1981 Upper Cretaceous and Lower Tertiary geology of the Chattahoochee River valley, western Georgia and eastern Alabama: Georgia Geological Society 16th Annual Field trip, 88 p. Rock-Color Chart Committee, 1963 Rock-color chart; Geological Society of America, New York. Schroder, C. H., 1982 Trace fossils of the Oconee Group and basal Barnwell Group of East-Central Georgia; GGS Bulletin 88, 125 p. Shearer, H.
K, 1917 A report on the bauxite and fuller's earth of the Coastal Plain of Georgia; GGS Bulletin 31, 340 p. Siple, G. E., 1967 Geology and ground water of the Savannah River Plant and vicinity, South Georgia;unpublished Master's thesis, University of South Carolina, 123 p.McFadden, S.S.;Hetrick, J.H.;Kellam, M.F.;Rodenback, S.A.;and Huddlestun, P.F., 1986 Geologic data of the Gulf Trough area, Georgia;GGS Information Circular 56, 345 p.Muthig, M.G.and Colquhoun, D.J., 1988 Formal recognition of two members within the Rhems Formation in Calhoun County, South Carolina;South Carolina Geology, vol.32,#1#2, p.11-19.Muthig, M.G., Colquhoun, D.J., and St.C.Kendall, C., 1990 Sequence stratigraphy of the Black Mingo Group (Lower Tertiary)in South Carolina, in-Zullo, V.A, Harris, W.B., and Price, V.(eds.), Savannah River region: Transition between the Gulf and Atlantic Coastal Plains;Proceedings of the second Bald Head Island conference on Coastal Plains geology;University of North Carolina at Wilmington and U.S.DOE, p.118-121.North American Commission on Stratigraphic Nomenclature, 1983 North American Stratigraphic Code;AAPG Bulletin, vol.67, no.5, p.841-875.Nystrom, P G.;Willoughby, R.H.;and Kite, L.E.;1982 in-Nystrom, P.G., and Willoughby, R.H., (eds.), Geological investigations related to the stratigraphy in the kaolin mining district, Aiken County, South Carolina;Carolina Geological Society Field Trip, 1982, p.121, 158-161.Oman, C.H., 1965 Micropaleontology of the Lisbon Formation of Alabama;unpublished Ph.D.dissertation, Florida State University, 101 p., 10 plates.Owen, V., Jr., 1963 Geology and ground-water resources of Lee and Sumter Counties, southwest Georgia;USGS Water-Supply Paper 1666,67 p.Palmer, K V.W., 1937 The Claibornian Scaphopoda, Gastropoda, and dibranchiate 77 Cephalopoda of the southeastern United States: Bull.Am.Paleontology, vol.7, no.32, 730 p.Pickering, S.M., 1970 Stratigraphy, paleontology, and economic geology of portions of Perry and Cochran quadrangles, Georgia;GGS Bulletin 81, 67 p.Price, V.;Fallaw, W.C.;and Thayer, P.A, 1992 Lower Eocene strata at the Savannah River Site, South Carolina;in-Zullo, V.A;Harris, W.B.;and Price, V.(eds.), Savannah River Region: Transition Between the Gulf and Atlantic Coastal Plains;Proceedings of the Second Bald Head Island Conference on Coastal Plains Geology, University of North Carolina and U.S.DOE, p.52-53.Prowell, D.C., Edwards, L.E., and Frederiksen, N.0., 1985a The Ellenton Formation in South Carolina-a revised age designation from Cretaceous to Paleocene; USGS Bulletin 1605-A, p.A63-A69.Prowell, D.C.;Christopher, R.A;Edwards.E.;Bybell, L.M.;and Gill, H.E., 1985b Geologic section of the up dip Coastal Plain from central Georgia to western South Carolina;USGS Miscellaneous Field Studies Map, MF-1737, 10 p.Reinhardt, J., and Gibson, T.G., 1981 Upper Cretaceous and Lower Tertiary geology of the Chattahoochee River valley, western Georgia and eastern Alabama: Georgia Geological Society 16th Annual Field trip, 88 p.Rock-Color Chart Committee, 1963 Rock-color chart;Geological Society of America, New York.Schroder, C.H., 1982 Trace fossils of the Oconee Group and basal Barnwell Group of East-Central Georgia;GGS Bulletin 88, 125 p.Shearer, H.K, 1917 A report on the bauxite and fuller's earth of the Coastal Plain of Georgia;GGS Bulletin 31, 340 p.Siple, G.E., 1967 Geology and ground water of the Savannah River Plant and vicinity, South Carolina; USGS Water-Supply Paper 1841, 113 P . Sloan, E., 1908 Catalogue of the mineral localities of South Carolina; South Carolina Geological Survey Bull. 2, 506 p. Smith, E. A., 1907 The underground water resources of Alabama; Alabama Geological Survey Monograph
- 6. Smith, E. A.; Johnson, L. C.; and Langdon, D. W., Jr., 1894 Report on the geology of the Coastal Plain of Alabama; Alabama Geological Survey Special Report 6. Snipes, D. S.; Fallaw, W. C.; and Price, V., 1992 Structural geology of the Savannah River Site in the Coastal Plain of South Carolina, h- Zullo, V. A.; Harris, W. B.; and Price, V. (eds.), Savannah River region:
Transition between the Gulf and Atlantic Coastal Plains; Proceedings of the second Bald Head Island Conference on Coastal Plains Geology; University of North Carolina at Wilmington and U. S. DOE, p. 33-36.
Snipes, D. S.; Fallaw, W. C.; Price, V., Jr.; and Cumbest, R. J., 1993 The Pen Branch fault: documentation of Late Cretaceous-Tertiary faulting in the Coastal Plain South Carolina; Southeastern Geology, vol. 33, no. 4, p. 195218. Stainforth, S. M.; Lamb, J. L.; Luterbacher, H.; Beard, J. H.; and Jeffords, R. M., 1976 Cenozoic planktonic foraminiferal zonation and characteristics of index forms: Univ. Kms. Paleo. Contributions, Article 62, 425 p. Steele, K B., 1986 Lithostratigraphic correlation of Cretaceous and younger strata of the Atlantic Coastal Plain Province within Aiken, Allendale and Barnwell Counties, South Carolina; unpublished Master's thesis, Univedty of South Carolina, 174 p. Summerour, J. H.; Shapiro, E. A.; Huddlestun, P. F.; and Hall, M. A,, 1996 An investigation of tritium in the Gordon and other aquifers in Burke County, Georgia-Phase I1 (inpmpamtion).
Toulmin, L. D., 1977 Stratigraphic distribution of Paleocene and Eocene fossils in the eastern Gulf Coast region; GSA Monograph 13, I, 602 p. Toulmin, L. D. and LaMoreaux, P. E., 1963 Stratigraphy along the Chattahoochee River, connecting link between Atlantic and Gulf Coastal Plains; AAPG Bulletin vol. 47, p. 385- 404. Van Nieuwenhuise, D. S., and Colquhoun, D. J., 1982a Contact relationships of the Black Mingo and Pee Dee Formations - the Cretaceous-Tertiary boundary in South Carolina, U.S.A.: South Carolina Geology, vol. 26, no. 1, p. 1-14. Van Nieuwenhuise, D. S., 19822, The Paleocene- Lower Eocene Black Mingo Group of the east central Coastal Plain of South Carolina:
South Carolina Geology, vol. 26, no. 2, p. 47-67. Veatch, O., and Stephenson, L. W., 1911 Preliminary report on the geology of the Coastal Plain of Georgia; GGS Bulletin 26, 466 p. Summerour, J. H.; Shapiro, E. A; Lineback, J. A.; Huddlestun, P. F.; and Hughes, A. C., 1994 An investigation of tritium in the Gordon and others aquifers in Burke County, Georgia; GGS Information Circular 95, 93 p. Carolinaj USGS Water-Supply Paper 1841, 113 p.Sloan, E., 1908 Catalogue of the mineral localities of South Carolinaj South Carolina Geological Survey Bull.2, 505 p.Smith, E.A, 1907 The underground water resources of Alabamaj Alabama Geological Survey Monograph 6.Smith, E.A.;Johnson, L.C.;and Langdon, D.W., Jr., 1894 Report on the geology of the Coastal Plain of Alabama;Alabama Geological Survey Special Report 6.Snipes, D.S.;Fallaw, W.C.;and Price, V., 1992 Structural geology of the Savannah River Site in the Coastal Plain of South Carolina, in-Zullo, V.A;Harris, W.B.;and Price, V.(eds.), Savannah River region: Transition between the Gulf and Atlantic Coastal Plains;Proceedings of the second Bald Head Island Conference on Coastal Plains Geologyj University of North Carolina at Wilmington and U.S.DOE, p.33-36.Snipes, D.S.;Fallaw, W.C.;Price, V., Jr.;and Cumbest, R.J., 1993 The Pen Branch fault: documentation of Late Cretaceous-Tertiary faulting in the Coastal Plain South Carolina;Southeastern Geology, vol.33, no.4, p.195-218.Stainforth, S.M.;Lamb, J.L.;Luterbacher, H.;Beard, J.H.;and Jeffords, R.M., 1975 Cenozoic planktonic foraminiferal zonation and characteristics ofindexfonns:
Univ.Kans.Paleo.Contributions, Article 62, 425 p.Steele, K B., 1985 Lithostratigraphic correlation of Cretaceous and younger strata of the Atlantic Coastal Plain Province within Aiken, Allendale and Barnwell Counties, South Carolinaj unpublished Master's thesis, University of South Carolina, 174 p.Summerour, J.H.;Shapiro, E.A;Lineback, J.A;Huddlestun, P.F.j and Hughes, A C., 1994 An investigation of tritium in the Gordon and others aquifers in Burke County, Georgiaj GGS Information Circular 95, 93 p.78 Summerour, J.H.jShapiro,E.
Aj Huddlestun, P.F.j and Hall, M.A, 1996 An investigation of tritium in the Gordon and other aquifers in Burke County, Georgia-Phase II (in preparation).
Toulmin, L.D., 1977 Stratigraphic distribution of Paleocene and Eocene fossils in the eastern Gulf Coast regionj GSA Monograph 13, I, 602 p.Toulmin, L.D.and LaMoreaux, P.E., 1963 Stratigraphy along the Chattahoochee River, connecting link between Atlantic and Gulf Coastal Plainsj AAPG Bulletin vol.47, p.404.Van Nieuwenhuise, D.S., and Colquhoun, D.J., 1982a Contact relationships of the Black Mingo and Pee Dee Formations
-the Tertiary boundary in South Carolina, U.S.A: South Carolina Geology, vol.26, no.1, p.1-14.Van Nieuwenhuise, D.S., 1982b The Lower Eocene Black Mingo Group of the east central Coastal Plain of South Carolina: South Carolina Geology, vol.26, no.2, p.47-67.Veatch, 0., and Stephenson, L.W., 1911 Preliminary report on the geology of the Coastal Plain of Georgiaj GGS Bulletin 26, 466 p.
APPENDIX 1 DESCRIPTIONS OF CORE SITE LOCATIONS GGS-3537 (Burke 6, McBean core) Location:
In northern Burke County, on the north shoulder of Collins Road, 1.4 airline miles (2.2 km) southeast of the Ga. Hwy. 56 bridge over McBean Creek, 1.1 miles (1.8 km) east of the intersection of Ga. Hwy. 56 and Collins Road, and 1.2 miles (1.9 km) southeast of the only remaining exposed McBean Limestone at the type locality.
The core site is in the McBean USGS 1:24,000 quadrangle map. GGS-3758 (Burke 6, USGS Millere Pond) Location:
M. A. Miller property, approximately
0.5 miles
south-southwest of the intersection of River Road and Millers Pond Road and approximately
0.5 miles
(0.8 km) north-northeast of Millers Pond, a dammed segment of Bow Gut Creek (a.k.a McKinney Branch) in northeastern Burke County, Georgia. The core site is in the McBean USGS 1:24,000 quadrangle map. 668-3164 (Burke 7, TR92-1) Location:
On Georgia Power Company property, on the shoulder of an unimproved road approximately 1 mile (1.6 km) south of Gobbie Grove Church and 1.75 miles (2.8 km) west-northwest of the intersection of Hancock Landing Road and River Road in eastern Burke County. The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map. GGS-3762 (Burke 8, TR92-2) Location:
In an abandoned trailer park on Hancock Landing Road, approximately 0.15 mile (0.1 km) east of the intersection of Hancock Landing Road and River Road, behind the abandoned Shell station and abandoned Southern Fried Chicken restaurant in eastern Burke County.
The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map. GGS-3781 (Burke 9, TR92-3) Location: On Georgia Power Company property, off Ebenezer Church Road, on the upland surface approximately 0.4 mile (0.6 km) south of Beaverdam Creek, approximately
2.4 miles
(3.8 km) north of the intersection of Ebenezer Church Road and Ga. Hwy. 23. It is also approximately 2 miles (3 km) south-southwest of Plant Vogtle in Burke Cdunty. The core site is in the Alexander USGS 1:24,000 quadrangle map. 668-3782 (Burke 10, TR92-4) Location: On Robert Mobley property, immediately southeast of Allen Chapel Road near the northwestern valley wall on an unnamed Savannah River tributary, approximately 1 mile (1.6 km) east of the intersection of Allen Chapel Road and River Road, and 2.8 miles (4.5 km) southeast of the intersection of River Road (Ga. Hwy. spur 56) and Ga. Hwy. 80 (Shell Bluff Landing Road) in eastern Burke County. The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map. APPENDIX 1 DESCWP1'IONS OF CORE SITE LOCATIONS GGS*3537 (Burke 6, McBean core)Location: In northern Burke County, on the north shoulder of Collins Road, 1.4 airline miles (2.2 km)southeast of the Ga.Hwy.56 bridge over McBean Creek, 1.1 miles (1.8 km)east of the intersection of Ga.Hwy.56 and Collins Road, and 1.2 miles (1.9 km)southeast of the only remaining exposed McBean Limestone at the type locality.The core site is in the McBean USGS 1:24,000 quadrangle map.GGS*3758 (Burke 6, USGS Millers Pond)Location: M.A.Miller property, approximately
0.5 miles
south-southwest of the intersection of River Road and Millers Pond Road and approximately
0.5 miles
(0.8 km)north-northeast of Millers Pond, a dammed segment of Boggy Gut Creek (a.k.a.McKinney Branch)in northeastern Burke County, Georgia.The core site is in the McBean USGS 1:24,000 quadrangle map.GGS*3764 (Burke 7, TR92*1)Location: On Georgia Power Company property, on the shoulder of an unimproved road approximately 1 mile (1.6 km)south of Gobbie Grove Church and 1.75 miles (2.8 km)west-northwest of the intersection of Hancock Landing Road and River Road in eastern Burke County.The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map.GGS*3762 (Burke 8, TR92*2)Location: In an abandoned trailer park on Hancock Landing Road, approximately 0.15 mile (0.1 km)east of the intersection of Hancock Landing Road and River Road, behind the abandoned Shell station and abandoned Southern Fried Chicken restaurant in eastern Burke County.The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map.GGS*3781 (Burke 9, TR92*3)Location: On Georgia Power Company property, off Ebenezer Church Road, on the upland surface approximately 0.4 mile (0.6 km)south of Beaverdam Creek, approximately
2.4 miles
(3.8 km)north of the intersection of Ebenezer Church Road and Ga.Hwy.23.It is also approximately 2 miles (3 km)south-southwest of Plant Vogtle in Burke C",unty.The core site is in the Alexander USGS 1:24,000 quadrangle map.GGS*3782 (Burke 10, TR92*4)Location: On Robert Mobley property, immediately southeast of Allen Chapel Road near the northwestern valley wall on an unnamed Savannah River tributary, approximately 1 mile (1.6 km)east of the intersection of Allen Chapel Road and River Road, and 2.8 miles (4.5 km)southeast of the intersection of River Road (Ga.Hwy.spur 56)and Ga.Hwy.80 (Shell Bluff Landing Road)in eastern Burke County.The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map.79 GGS-3792 (Burke 11, TR92-5) Location:
In DeLaigle Mobile Home Park (A & A Trailer Park), on River Road, approximately 0.5 mile (0.8 km) west of Georgia Power Company Plant Vogtle near the large horizontal water tank. The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map. GGS-3794 (Burke 12, TR92-6) Location:
Thomeon Oak Flooring Company property, near the edge of the blu£* overlooking the Savannah River flood plain, approximately
1.8 miles
(2.9 km) northwest of Hancock Landing on the Savannah River in Burke County, Georgia. The core site is in the Shell Bluff Landing USGS 1:!24,000 quadrangle map. USGS Girard core Location:
Adjacent to a fire lookout tower on Grif6ns Landing Road, 0.75 mile (0.45 km) north of the intersection of Gfins Landing Road and Ga. Hwy. 23 and approximately
1.8 miles
(2.9 km) north of Girard in southeastern Burke County. The core site is in the Girard USGS 1:24,000 quadrangle map. Bechtel core VG-1 Location:
On the northeast shoulder of River Road, approximately
1.1 miles
(1.76 km) northwest of the crossing of Sweetwater Creek. The core site is in the Girard USGS 1:24,000 quadrangle map. Bechtel core VG-2 Location:
On the shoulder of River Road near the southeast corner of the intersection of River Road and Brighams Landing Road. The core site is in the Girard USGS 1:24,000 quadrangle map in southeastern Burke County, Georgia. Bechtel core VG-3 Location:
On the northeastern shoulder of River Road, on the northern valley wall of Old Mill Branch valley, immediately northwest of the River Road crossing of this dry creek bed. The core site is in the Girard USGS l:24OOO quadrangle map, in southeastern Burke County, Georgia. Bechtel core VG-4 Location:
On the northeastern shoulder of River Road, on the southeast valley wall of Little Beaverdam Creek.
The core site is in the Girard USGS 1:!24,000 quadrangle map, in southeastern Burke County, Georgia. Bechtel core VGS Location:
Near the foot of the eastam valley side of Sw&water Creek and Still Branch, on the shoulder of River Road appnximately 0.15 mile (026 km) east ofthe bridge over Sweetwater Creek The core site of the VG-5 is at the boundary of the USGS 1:24,000 quadrangle map8 Gii Ga-S.C and Millett, S.C.-Ga in southern Burke County, Georgia. GG8-3792 (Burke 11, TR92*5)Location: In DeLaigle Mobile Home Park (A&A Trailer Park), on River Road, approximately 0.5 mile (0.8 km)west of Georgia Power Company Plant VogUe near the large horizontal water tank.The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map.GGS*3794 (Burke 12, TR92*6)Location: Thomson Oak.Flooring Company property, near the edge of the bluff overlooking the Savannah River flood plain, approximately
1.8 miles
(2.9 km)northwest of Hancock Landing on the Savannah River in Burke County, Georgia.The core site is in the Shell Bluff Landing USGS 1:24,000 quadrangle map.USGS Girard core Location: Adjacent to a fire lookout tower on Griffins Landing Road, 0.75 mile (0.45 km)north of the intersection of Griffins Landing Road and Ga.Hwy.23 and approximately
1.8 miles
(2.9 km)nort;p of Girard in southeastern Burke County.The core site is in the Girard USGS 1:24,000 quadrangle map.Bechtel core VG-l Location: On the northeast shoulder of River Road, approximately
1.1 miles
(1.76 km)northwest of the crossing of Sweetwater Creek.The core site is in the Girard USGS 1:24,000 quadrangle map.Bechtel core VG*2 Location: On the shoulder of River Road near the southeast comer of the intersection of River Road and Brighams Landing Road.The core site is in the Girard USGS 1:24,000 quadrangle map in southeastern Burke County, Georgia.Bechtel core VG*3 Location: On the northeastern shoulder of River Road, on the northern valley wall of Old Mill Branch valley, immediately northwest of the River Road crossing of this dry creek bed.The core site is in the Girard USGS 1:24,000 quadrangle map, in southeastern Burke County, Georgia.Bechtel core VG*4 Location: On the northeastern shoulder of River Road, on the southeast valley wall of Little Beaverdam Creek.The core site is in the Girard USGS 1:24,000 quadrangle map, in southeastern Burke County, Georgia.Bechtel core VG-5 Location: Near the foot of the eastern valley side of Sweetwater Creek and Still Branch, on the shoulder of River Road approximately 0.15 mile (0.26 km)east of the bridge over Sweetwater Creek.The core site of the VG-5 is at the boundary of the USGS 1:24,000 quadrangle maps Girard, Ga.-8.C and Millett, S.C.-Ga in southern Burke County, Georgia.80 Bechtel core VG6 Location: On the shoulder of River Road at the intersection with an unimproved county road, approximately
1.4 miles
(2.2 km) southeast of the River Road bridge over Sweetwater Creek, and 3 miles (6 km) from the Burke/Screven Counties line in southern Burke County, Georgia. The core site is located in the Millett, S.C.-Ga., USGS 1:24,000 quadrangle map. Bechtel core VG-7 Location: On the shoulder of River Road near the northeast corner of the intersection of River Road and G-ns Landing Road. The core site is in the Girard USGS 1:24,000 quadrangle map in southeastern Burke County, Georgia. Bechtel core VG-8 Location:
On the northeast shoulder of River Road bridge, on the northwest site of the pond formed by the damming of Little Sweetwater Creek. Approximately
.65 miles (10.4 km) northwest of the intersection of River Road and Stony Bluff Road. The core site is located in the Millett, S.C.-Ga., USGS 1:24,000 quadrangle map. Georgia Power core B-246 Location:
On Georgia Power Company Plant Vogtle property, on an upland spur or lead, overlooking the southern end of Utleys Pond, slightly less than 0.1 mile (1.4 km) west of the end of Utleys Pond (also referred to as Mallards Pond). The core site is located in the Shell Bluff Landing, USGS 1:24,000 quadrangle map. The core was inadvertently destroyed in the late 1970's while in storage at Georgia Power Plant Vogtle, but a log of the core is available at the Georgia Geologic Survey in Atlanta. CORE SITES OUTSIDE BURKE COUNTY Bechtel core VSC-3 Location: On shoulder of dirt road, 0.5 mile (0.3 km) north-northeast of St. Marys Church; St.
Marys Church is on the north side of S.C. Hwy. 125, 0.4 mile (0.25 km) west of the Barnwell-Allendale County in Barnwell County, South Carolina.
The core site of the Bechtel VSC-3 is located in the Girard NE USGS 1:24,000 quadrangle map. Bechtel core VSC-4 Location; On the northern valley wall of the Savannah River, less than 0.1 mile (0.16 km) north of S.C. Hwy. 125, less than 0.1 mile (0.16 km) west of Barnwell-AUendale County line, 2.2 miles (3.5 km) northeast of Savannah River in AUendale County, South Carolina. The core site of the Bechtel VSC-4 is located in the Millett S.C.-Ga., USGS 1:24,000 quadrangle map. Bechtel core VG-6 Location: On the shoulder of River Road at the intersection with an unimproved county road, approximately
1.4 miles
(2.2 kIn)southeast of the River Road bridge over Sweetwater Creek., and 3 miles (5 kIn)from the Burke/Screven Counties line in southern Burke County, Georgia.The core site is located in the Millett, S.C.-Ga., USGS 1:24,000 quadrangle map.Bechtel core VG-7 Location: On the shoulder of River Road near the northeast comer of the intersection of River Road and Griffins Landing Road.The core site is in the Girard USGS 1:24,000 quadrangle map in southeastern Burke County, Georgia.Bechtel core VG*8 Location: On the northeast shoulder of River Road bridge, on the northwest site of the pond formed by the damming of Little Sweetwater Creek.Approximately
.65 miles (l0.4 km)northwest of the intersection of River Road and Stony Bluff Road.The core site is located in the Millett, S.C.-Ga., USGS 1:24,000 quadrangle map.Georgia Power core B*246 Location: On Georgia Power Company Plant Vogtle property, on an upland spur or lead, overlooking the southern end of Utleys Pond, slightly less than 0.1 mile (1.4 km)west of the end of Utleys Pond (also referred to as Mallards Pond).The core site is ldcated in the Shell Bluff Landing, USGS 1:24,000 quadrangle map.The core was inadvertently destroyed in the late 1970's while in storage at Georgia Power Plant Vogtle, but a log of the core is available at the Georgia Geologic Survey in Atlanta.CORE SITES OUTSIDE BURKE COUNTY Bechtel core VSC*3 Location: On shoulder of dirt road, 0.5 mile (0.3 kIn)north-northeast of St.Marys Church;St.Marys Church is on the north side of S.C.Hwy.125, 0.4 mile (0.25 kIn)west of the Barnwell-Allendale County in Barnwell County, South Carolina.The core site of the Bechtel VSC-3 is located in the Girard NE USGS 1:24,000 quadrangle map.Bechtel core VSC*4 Location;On the northern valley wall of the Savannah River, less than 0.1 mile (0.16 km)north of S.C.Hwy.125, less than 0.1 mile (0.16 kIn)west of Barnwell-Allendale County line, 2.2 miles (3.5 km)northeast of Savannah River in Allendale County, South Carolina.The core site of the Bechtel VSC-4 is located in the Millett S.C.-Ga., USGS 1:24,000 quadrangle map.81 668-3187 (Dougherty 2, USGS Albany core)
Location:
Dougherty County, approximately 0.2 mile (0.3 km) east-northeast of the intersection of U.S. Hwy. 19 and a county road, approximately 0.8 mile (0.13 km) south of the intersection of U.S. Hwy. 19 and Holley Highway (Ga. Hwy. 257). The core site is on the Albany East USGS 1:24,000 quadrangle map. 668-3366 (Sumter 9A) Location:
Sumter County, approximately 0.75 mile (0.12 km) north of Ga. Hwy. 27 and approximately 0.5 mile (0.8 km) west of the Flint River, near the site of the old Danville Ferry. This site is located in the Drayton USGS 1:24,000 quadrangle map. Location:
On the south shoulder of a paved county road, approximately 200 feet northeast of the Pulaski fire tower, 0.35 mile (0.2 km) west of the intersection of the paved county road and U.S. Hwy. 129, 1.9 miles (1.1 km) south of the intersection of Broad Street (U.S. Hwy. 341) and U.S. Hwy. 129 in Hawkinsville, Georgia. The core site is on the Hawkinsville USGS 1:24,000 quadrangle map. 668-3511 (Pulaski 5, Pulaeki County core, Arrowhead core) Location:
On the top of a hill, approximately 1.7 miles (2.7 km) west of Ga. Hwy. 26 and 0.5 mile (0.8 km) southwest of the Bleckley-Pulaski Counties line in northern Pulaski County. The core site is in the southwestern corner of the West Lake USGS 1:24,000 quadrangle map. 668-3545 (Colquitt 11, Doe Run core) Location:
on Harrell farm property, on a valley side between an unimproved county road and a farm pond, 0.25 mile (0.15 km) east of junction of the county road and Ga. Hwy. 133, approximately
2.0 miles
(1.2 km) southeast of the intersection of Ga. Hwy. 133 and Ga. Hwy. 270 in Doe Run, Colquitt County, Georgia (also see McFadden and others, 1986, p. 323). The core site is in the Doe Run USGS 1:24,000 quadrangle map. 668-3523 (Laurene 1, Laurene County core) Location:
In an east-bound Interstate 16 rest area, 2.8 miles (4.5 km) east of the intersection of Interstate Hwy. 16 and Ga. Hwy. 338. The core site is in the southern part of the Dudley USGS 1:24,000 quadrangle map. GGS*3187 (Dougherty 2, USGS Albany core)Location: Dougherty County, approximately 0.2 mile (0.3 kIn)east-northeast of the intersection of U.S.Hwy.19 and a county road, approximately 0.8 mile (0.13 kIn)south of the intersection of U.S.Hwy.19 and Holley Highway (Ga.Hwy.257).The core site is on the Albany East USGS 1:24,000 quadrangle map.GGS-3366 (Sumter 9A)Location: Sumter County, approximately 0.75 mile (0.12 kIn)north of Ga.Hwy.27 and approximately 0.5 mile (0.8 kIn)west of the Flint River, near the site of the old Danville Ferry.This site is located in the Drayton USGS 1:24,000 quadrangle map.GGS*3111 (Pulaski 3)Location: On the south shoulder of a paved county road, approximately 200 feet northeast of the Pulaski:lire tower, 0.35 mile (0.2 kIn)west of the intersection of the paved county road and U.S.Hwy.129, 1.9 miles (1.1 kIn)south of the intersection of Broad Street<U.S.Hwy.341)and U.S.Hwy.129 in Hawkinsville, Georgia.The core site is on the Hawkinsville USGS 1:24,000 quadrangle map.GGS*3511 (Pulaski 5, Pulaski County core, Arrowhead core)Location: On the top of a hill, approximately
1.7 miles
(2.7 kIn)west of Ga.Hwy.26 and 0.5 mile (0.8 kIn)southwest of the Bleckley-Pulaski Counties line in northern Pulaski County.The core site is in the southwestern corner of the West Lake USGS 1:24,000 quadrangle map.GGS-3545 (Colquitt 11, Doe Run core)Location: on Harrell farm property, on a valley side between an unimproved county road and a farm pond, 0.25 mile (0.15 kIn)east of junction of the county road and Ga.Hwy.133, approximately
2.0 miles
(1.2 kIn)southeast of the intersection of Ga.Hwy.133 and Ga.Hwy.270 in Doe Run, Colquitt County, Georgia (also see McFadden and others, 1986, p.323).The core site is in the Doe Run USGS 1:24,000 quadrangle map.GGS*3523 (Laurens 1, Laurens County core)Location: In an east-bound Interstate 16 rest area, 2.8 miles (4.5 kIn)east of the intersection of Interstate Hwy.16 and Ga.Hwy.338.The core site is in the southern part of the Dudley USGS 1:24,000 quadrangle map.82 APPENDIX 2 HISTORICAL REWEW OF BLACK MINGO AND ELLENTON FORMATIONS The undifferentiated Black Mingo Formation of this report previously, in Burke County, had been referred to the Ellenton Formation of Siple (1967) (Bechtel, 1982; Harris and Zullo, 1990). Prowell and others (198Sb) described a core section of the Ellenton Formation from SRS (not at the site of the type locality) and determined that the Ellenton in its type area consisted of a lower, Lower Paleocene part (Midwayan) and an upper, Upper Paleocene part (lower Sabinian).
Similarly, early paleontologic observations (Sloan, 1908; Cwke, 1936) of the Black Mingo Formation and recent palynological studies of the Black Mingo Formation and the Ellenton Formation of Siple (1967) Wan Nieuwenhuise and Colquhoun, 1982; Muthig and others, 1990) indicate that the Black Mingo and Ellenton are Early Paleocene to Late Paleocene in age (i.e., two discrete biostratigraphic and chronoatratigraphic units). This resulted in questioning or abandoning the name Ellenton and replacing the name Ellenton with names of subdivisions of the Black Mingo Formation (or Group). The Black Mingo has not been formally recognized in Georgia. The type area of the formation is in the central Coastal Plain of South Carolina where the name has been used since 1908. It is to be noted that in the type area of the Black Mingo Formation, the Black Mingo is an off-shore, fossiliferous, continental shelf deposit.
In SRS and northern Burke County. the correlative deposits are inner continental shelf with some coastal marine lithofacies.
As a results, there are some differences in the gross lithologies of the correlative deposits.
The historical development of the Black Mingo concept has been restricted to South Carolina but, because the name has been informally used in Georgia, and the Black Mingo is crucial to understanding the Ellenton, the historical usage of the name is of concern in Georgia as well. Sloan (1907, 1908) named the Black Mingo stratigraphic unit but his use of the name was vague. He referred to it as: "Black Mingo Phasew, "Lower Black Mingo seriesw, " Lower Black Mingo", "Black Mingo Shale", "Upper and Lower Black Mingo formations", "Upper Black Mingo", "Upper Black Mingo phase or Rhema Shalew, "Rhems Shale", "Upper Black Mingo (Rhems and Williamsburg").
WilliamsburgPseudo-Buhrstonen, 'Williamsburg Pseudo-Buhrw, "Lang Syne beds", "Lang Syne?" (Sl~an, 1908, p. 449-452).
The Upper Black Mingo formations are observed in Williamsburg County near Rhems, ... (p. 461) ... shales and pseudo-buhratone with Eocene fossils, ... interpreted as the probable equivalent of the Upper Black Mingo (p. 451- 462) .... The Lower Black Mingo formations afford the first expression of the great land subsidence which caused the shore line to retreat inland at the beginning of the Eocene period.
The type exposure is at Perkins Bluff on the Black River near its confluence with the Black Mingo River. (p. 462) The Upper Black Mingo was inaugurated by a renewal of sedimentation which afforded additional gray laminated shales inclosing a small variety of the Venericardia planicosta in the form of molds and casts, best exhibited at Rhems Landing on the Black Mingo River (p. 462). At Lang Syne and Warley Hill the Congaree shales rest on fine grained, black, slightly glauconitic, sand and partly indurated gray sands, both of which contain tender casts of small shells. We shall refer to them as the Lang Syne beds. Stratigraphically they belong below the Congaree shales, and are tentatively treated as a part of the Black Mingo, pending further investigations.
It is recognized that there is a faunal advance from the Lower to the Upper Black Mingo formations, but in so much as the later are so intimately associakd over a large area, without stratigraphic break, it has been decided that the distinction of Upper and Lower will prove satkhctory for the general discrimination of these beds. The Upper Black Mingo comprises: (a) The Wiamsburg Pseudo- Buhr consisting of yellow-red sands which inclose a hard silicified ledge about two feet thick, in which casts of Ostrea msis and the Venericardia planicosta occur ... (p. 452) 01) Rhema Shale. Light gray to black shale APPENDIX 2 HISTORICAL REVIEW OF BLACK MINGO AND ELLENTON FORMATIONS The undifferentiated Black Mingo Formation of this report previously, in Burke County, had been referred to the Ellenton Formation of Siple (1967)(Bechtel, 1982;Harris and Zullo, 1990).Prowell and others (1985b)described a core section of the Ellenton Formation from SRS (not at the site of the type locality)and determined that the Ellenton in its type area consisted of a lower, Lower Paleocene part (Midwayan) and an upper, Upper Paleocene part (lower Sabinian).
Similarly, early paleontologic observations (Sloan, 1908;Cooke, 1936)of the Black Mingo Formation and recent palynological studies of the Black Mingo Formation and the Ellenton Formation of Siple (1967)(Van Nieuwenhuise and Colquhoun, 1982;Muthig and others, 1990)indicate that the Black Mingo and Ellenton are Early Paleocene to Late Paleocene in age (i.e., two discrete biostratigraphic and chronostratigraphic units).This resulted in questioning or abandoning the name Ellenton and replacing the name Ellenton with names of subdivisions of the Black Mingo Formation (or Group).The Black Mingo has not been formally recognized in Georgia.The type area of the formation is in the central Coastal Plain of South Carolina where the name has been used since 1908.It is to be noted that in the type area of the Black Mingo Formation, the Black Mingo is an off-shore, fossiliferous, continental shelf deposit In SRS and northern Burke County.the correlative deposits are inner continental shelf with some coastal marine lithofacies.
As a results, there are some differences in the gross lithologies of the correlative deposits.The historical development of the Black Mingo concept has been restricted to South Carolina but, because the name has been informally used in Georgia, and the Black Mingo is crucial to understanding the Ellenton, the historical usage of the name is of concern in Georgia as well.Sloan (1907, 1908)named the Black Mingo stratigraphic unit but his use of the name was vague.He referred to it as: "Black Mingo Phase","Lower Black Mingo series"," 83 Lower Black Mingo","Black Mingo Shale","Upper and Lower Black Mingo formations","Upper Black Mingo","Upper Black Mingo phase or Rhems Shale","Rhems Shale","UpperBlack Mingo (Rhems and Williamsburg")."WilliamsburgPseudo-Buhrstone",'Williamsburg Pseudo-Buhr","Lang Syne beds","Lang Syne?" (Sloan, 1908, p.449-452).The Upper Black Mingo formations are observed in Williamsburg County near Rhems,...(p.451)...shales and pseudo-buhrstone with Eocene fossils,...interpreted as the probable equivalent of the Upper Black Mingo (p.452)....The Lower Black Mingo formations afford the first expression of the great land subsidence which caused the shore line to retreat inland at the beginning of the Eocene period.The type exposure is at Perkins Bluff on the Black River near its confluence with the Black Mingo River.(p.452)The Upper Black Mingo was inaugurated by a renewal of sedimentation which afforded additional gray laminated shales inclosing a small variety of the Venericardia planicosta in the form of molds and casts;best exhibited at Rhems Landing on the Black Mingo River (p.452).At Lang Syne and Warley Hill the Congaree shales rest on fine grained, black, slightly glauconitic, sand and partly indurated gray sands, both of which contain tender casts of small shells.We shall refer to them as the Lang Syne beds.Stratigraphically they belong below the Congaree shales, and are tentatively treated as a part of the Black Mingo, pending further investigations.
It is recognized that there is a faunal advance from the Lower to the Upper Black Mingo formations, but in so much as the later are so intimately over a large area, without stratigraphic break, it has been decided that the distinction of Upper and Lower will prove satisfactory for the general discrimination of these beds.The Upper Black Mingo comprises: (a)The WilliamsburgBuhr consisting of yellow-red sands which inclose a hard silicified ledge about two feet thick, in which casts of Ostrea arrasis and the Venericardia planicosta occur...(p.452)(b)Rhems Shale.Light gray to black shale interlaminated with thin seams of fine grained sand and mica. ... (p. 453). It is clear that Sloan (1908) recognized lower and upper subdivisions of the Black Mingo, but the distinctions appear to be related more to paleontology (age) and stratigraphic position than to lithology. However, Sloan (1908) considered the type "exposure" of the lower Black Mingo to be at Perkins Bluff and the Upper Black Mingo being best exhibited at Rhems Landing. Both the sections exposed at Rhems Landing and Perkins Bluff are now considered to be lower Black Mingo (Van Nieuwenhuise and Colquhoun, 198213). Cooke (1936, p. 41) was the first to describe the formation in a more modern context. He paraphrased Sloan's use of the name Black Mingo as follows: "The name "Black Mingo shales", taken from Black Mingo Creek, a tributary of the Black River in Williamsburg and Georgetown Counties, S. C., was applied by Sloan in 1907 to laminated sandy shale exposed along the Black River from Brewington Luke, in Clarendon County, to the mouth of Black Mingo Creek, and up Black Mingo Creek to a point between Rhems and the General Marion Bridge. In 1908, he extended the name to a more comprehensive unit, his Black Mingo 'Iphase", which included all the strata of lower Eocene age east of the Santee River." Cooke (1936, p. 41) applied the name Black Mingo Formation to all Tertiary strata older than the "McBean" Formation, including the Congaree Formation, and correlated it (Black Mingo) mainly with the Tuscahoma Formation of the eastern Gulf Coastal Plain.
However, Cooke and MacNeil (1952, p. 21-21) later correlated the Black Mingo with the lower Wilcox, Nanafalia Formation of the eastern Gulf Coast. Their (Cooke, 1936; Cooke and MacNeil, 1952) correlation was based on macrofossils from the more marine, type area of the Black Mingo Formation.
Siple (1967, p. 28-31) introduced the name Ellenton Formation for what he considered to be an Upper Cretaceous unit that overlay the "Tuscaloosatt Formation in the subsurface of the Savannah River Plant in western South Carolina.
The type section of the Ellenton Formation is the interval 310 feet to 385 f&t in well 62-C in SRS. A reformatted type description of the Ellenton Formation as given by Siple (1967, p. 29) is as follows: Cmincwud (9 2&&m-EUenton Fomation-(31 0- 335 feet)-% foot thick clay, bluish-gmy, micaceoua, lignitic sandy; muscovite common to abundant; altered pyrite or mamite fairly common. Subangular to submunded fine medium quartz grains. Trace of chlorite.
Interval from 325335 feet predominantly clay. (335345 feet)-10 foot thick sand, coarse, clayey, micaceoua lignitig subangular milky quartz; dark gray clay; minor percentage shows conchoidal fractures.
Heavy minerals in mre to trace amounts-may be contamination.
(345365 feet)-20 foot thick sand, same as above except for appearance of colorless acicular crystals of gypsum (selenite) in the dark gray clay. Other gypsifemus fonns noted include satin spar. Some of the lignite replaced by pyrite or mamite; 55 percent of sand coarse to very coarse. Laboratory determination ofpermability indicates 66 gpd (Meinzer's units). (365-370 feet)-5 foot thick sand, white to gray, clayey and silty, micaceous and lignitic. Subangular fine to coarse quartz. Driller logged interval as clay. Twrccrloosa Formation-(370-385 ft.)-15 foot thick Sand, tan toyellow, clayey, micaceous, kaolinitic; contains scattered red ferruginous sand nodules. Siple (1967, p. 28-29) described the Ellenton as follows: The Ellenton Formation consists of a dark-gray to black sandy lignitic micaceous clay interbedded with medium to coarse quartz sand. Some of the quartz grains contain inclusions of pyrite, others are rutilated.
Much of the free pyrite appears to be decomposed.
Authigenic gypsum crystals are commonly distributed throughout the fornation.
Genemlly, the upper part of the formation contains a gray silty to sandy miccrceous lignitic clay with which the gypsum is commonly associated.
In some wells the clay zone may be overlain by coarse quartz sand. The lower part of the Ellenton consists genemlly of clayey quartz sand of medium to coarse texture, which in some areas becomes very coarse and gravelly.
The quartz grains are bluish gray. Lignite and decomposed pyrite or marcasite
@zgments, muscovite, and aggregates of kaolinite or other very sop minerals are fairly interlaminated with thin seams of fine grained sand and mica....(p.453).It is clear that Sloan (1908)recognized lower and upper subdivisions of the Black.Mingo, but the distinctions appear to be related more to paleontology (age)and stratigraphic position than to lithology.
However, Sloan (1908)considered the type"exposure" of the lower Black.Mingo to be at Perkins Bluff and the Upper Black Mingo being best exhibited at Rhems Both the sections exposed at Rhems Landing and Perkins Bluff are now considered to be lower Black Mingo (Van Nieuwenhuise and Colquhoun, 1982b).Cooke (1936, p.41)was the first to describe the formation in a more modern context.He paraphrased Sloan's use of the name Black Mingo as follows: "The name"Black Mingo shales", taken from Black Mingo Creek, a tributary of the Black River in Williamsburg and Georgetown Counties, S.C., was applied by Sloan in 1907 to laminated sandy shale exposed along the Black River from Brewington Lake, in Clarendon County, to the mouth of Black Mingo Creek, and up Black Mingo Creek to a point between Rhems and the General Marion Bridge.In 1908, he extended the name to a more comprehensive unit, his Black Mingophase, which included all the strata of lower Eocene age east of the Santee River." Cooke (1936, p.41)applied the name Black Mingo Formation to all Tertiary strata older than the"McBean" Formation, including the Congaree Formation, and correlated it (Black Mingo)mainly with the Tuscahoma Formation of the eastern Gulf Coastal Plain.However, Cooke and MacNeil (1952, p.21-21)later correlated the Black Mingo with the lower Wilcox, Nanafalia Formation of the eastern Gulf Coast.Their (Cooke, 1936;Cooke and MacNeil, 1952)correlation was based on macrofossils from the more marine, type area of the Black Mingo Formation.
Siple (1967, p.28-31)introduced the name Ellenton Formation for what he considered to be an Upper Cretaceous unit that overlay the"Tuscaloosa" Formation in the subsurface of the Savannah River Plant in western South Carolina.The type section of the Ellenton Formation is the interval 310 feet to 84 385 feet in well 52-C in SRS.A reformatted type description of the Ellenton Formation as given by Siple(1967,p.29)is as follows: Cretaa!olUl
('i)System-Ellenton Formotion-335 feet)-25 foot thick clay, bluish-gray, micaceous, lignitic sandy;muscovite common to abundant;altered pyrite or marcasite fairly common.Subangular to subrounded fine medium quartz grains.Trace of chlorite.Interval from feet predominantly clay.
feet)-10 foot thick sand, coarse, clayey, micaceous lignitic;subangular milky quartz;dark gray clay;minor percentage shows conchoidal fractures.
Heavy minerals in rare to trace amounts-may be contamination.
(345-365 feetJ-20 foot thick sand, same as above except for appearance of colorless acicular crystals of gypsum (selenite) in the dark gray clay.Other gypsiferous forms noted include satin spar.Some of the lignite replaced by pyrite or marcasite; 55 percent of sand coarse to very coarse.Laboratory determination of permeability indicates 66 gpd (Meinzer's units).(365-370 feet)-5 foot thick sand, white to gray, clayey and silty, micaceous and lignitic.Subangular fine to coarse quartz.Driller logged interval as clay.Tuscaloosa Formotion-(370-385 ft.)-15 foot thick Sand, tan to yellow, clayey, micaceous, kaolinitic; contains scattered red ferruginous sand nodules.Siple (1967, p.28-29)described the Ellenton as follows: The Ellenton Formation consists of a dark-gray to black sandy lignitic micaceous clay interbedded with medium to coarse quartz sand.Some of the quartz grains contain inclusions of pyrite, others are rutilated.
Much of the free pyrite appears to be decomposed.
Authigenic gypsum crystals are commonly distributed throughout the formation.
Generally, the upper part of the formation contains a gray silty to sandy micaceous lignitic clay with which the gypsum is commonly associated.
In some wells the clay zone may be overlain by coarse quartz sand.The lower part of the Ellenton consists generally of clayey quartz sand of medium to coarse texture, which in some areas becomes very coarse and gravelly.The quartz grains are bluish gray.Lignite and decomposed pyrite or marcasite fragments, muscovite, and aggregates of kaolinite or other very soft minerals are fairly common. The Ellenton Formution pmbably is unconformable with the underlying Tuscaloosa Formution and the overlying Tertiary sediments.
The lower contact is chrrmcterized by a change in color of the clay and a change in the composition of the sand. The dark-gmy to black clay of the Ellenton is readily distinguishable fivm the variegated clay of the Tuscaloosa likewise, the quartzose sand of the Ellenton can genemlly be diffeerentiated fivm the arkosic sand of the Tuscaloosa The upper contact is also characterized by a change in the color of the clay above and below the contact. ... The type-locality well for the Ellenton Formution is well 52-C which is 4 miles northeast of the town of Ellenton and 7 3/4 miles southeast of Jackson, Aiken County, S.
C. ... The Ellenton Formation was penetrated in the type well at a depth of 31 0 to 370 feet. ... (Siple, 1967). The type section consisted of well- cuttings from 52-C but the cuttings are now lost. In general in SRS and eastern Burke County, the basic criteria for identification of the Ellenton Formation were the consistent presence of carbonaceous and lignitic material in the formation, the prevalence of well-sorted, fine- grained sand, and the unit's prevailingly neutral tones of white to gray to black. Subsequent authors adopted the name Ellenton (Bechtel, 1982; Prowell and others, 1985a; Prowell and others, 198%; Harris and Zullo, 1990). Others have not (Fallaw and Price, 1992, 1995). Van Nieuwenhuise and Colquhoun (1982b, p. 52) reintroduced the Rhems and Williamsburg of Sloan (1908) in the type area of the Black Mingo: "The Black Mingo Shale, Rhems, Williamsbuqg and Lang Syne subphases of formations of Sloan (1908) comprise what is herein defined as the Black Mingo Gmup. Elevation of the Black Mingo to group status is actually only erecognition of the range implied by Sloan (1908) who considered the "Black Mingo Phase" as an aggrvgation of several formations or "subphasesf!
However, redefinition of the composite formations of the Black Mingo Group is necessary in order to eliminate a great deal of confusion in the literaiure and to incorporate the much more detailed stmtigraphic data now available." Further, Van Nieuwenhuise and Colquhoun (1982b) divided their Rhems Formation into a lower Bms Ferry Member and an upper Perkins Bluff Member. The Browns Ferry (lower) and Perkins Bluff (upper) Members (Fig. v) of the Rhems were considered to grade laterally and vertically into each other. Van Nieuwenhuise and Colquhoun (1982b) also divided the Williamsburg Formation into a lower Bridge Member and an upper Chicora Member.
The Lower Bridge Member was also described as grading vertically and laterally, in part, into the overlying Chicora Member.
According to Van Nieuwenhuise and Colquhoun (1982b, p. 54,): 'The Rhems Shale of Sloan (1908) is a distinctive shale containing almost no sand-sized particles and very few calcareous micmfossils.
... The type Rhems of Sloan (1 908) at Rh Landing is considered to be the finer-grained end member of the total range of the fine-grained clastics comprising the Browns Ferry Member." and "The lithology of the type Black Mingo Shale of Sloan (1908) is characteristic of a greater portion of the Browns Ferry Member and also the overall Rhems Formution than any of the other composite lithologies. " Van Nieuwenhuise and Colquhoun (1982b) did not fully discuss the lithologies of the Black Mingo formations and their members. They described the Browns Ferry Member, which evidently is the principal concept of their Rhems Formation, as an "arenaceous mud" , clayey sand or, generally, as a silty clay. They (p. 54) described the Perkins Bluff Member of the Rhems Formation as an: "...imbricated, pelecypod-rich. argillaceous sand
... resistant, partially silicified Perkins Bluff Member forms a prominent ridge that extends along the Black River and overhangs the Brownc Ferry Member seveml feet near river level." and "The Perkins Bluff Member lithology is considered somewhat variable but throughout maintains a coarser- grained texture than the Browns Ferry Member.
Parts of the Perkins Bluff member are almost "coquinq" such as at its type locality, but grade to an argillaceous sand with numerous pelecypods either as fragments, internal molds, or whole shells." (Van Nieuwenhuise and Colquhoun, 19823). common.The Ellenton Fonnation probably i8 unconformable with the underlying Tuscaloosa Fonnation and the overlying Tertiary sediments.
The lower contact is characterized by a change in color of the clay and a change in the composition of the sand.The dark-gray to black clay of the Ellenton i8 readily di8tinguishable from the variegated clay of the Tuscaloosa.
likewi8e, the quartzose sand of the Ellenton can generally be differentiated from the arkosic sand of the Tuscaloosa.
The upper contact is also characterized by a change inthecolor of the clay above and below the contact....The type-locality well for the Ellenton Fonnation is well 52-C which is 4 miles northeast of the town of Ellenton and 7 3/4 miles southeast of Jackson, Aiken County, S.C....The Ellenton Fonnation was penetrated in the type well at a depth of 310 to 370 feet....(Siple, 1967).The type section consisted ofcuttings from 52-C but the cuttings are now lost.In general in SRS and eastern Burke County, the basic criteria for identification of the Ellenton Formation were the consistent presence of carbonaceous and lignitic material in the formation, the prevalence of well-sorted,grained sand, and the unit's prevailingly neutral tones of white to gray to black.Subsequent authors adopted the name Ellenton (Bechtel, 1982;Prowell and others, 19800;Prowell and others, 1985b;Harris and Zullo, 1990).Others have not (Fallaw and Price, 1992, 1995).Van Nieuwenhuise and Colquhoun (1982b, p.52)reintroduced the Rhems and Williamsburg of Sloan (1908)in the type area of the Black Mingo: "The Black Mingo Shale, Rhems, Williamsburg and Lang Syne subphases of fonnations of Sloan (1908)comprise what is herein defined as the Black Mingo Group.Elevation of the Black Mingo to group status is actually only recognition of the range implied by Sloan (1908)who considered the"Black Mingo Phase" as an aggregation of several fonnations or"subphases".
However, redefinition of the composite fonnations of the Black Mingo Group is necessary in order to eliminate a great deal of confusion in the literature and to incorporate the much more detailed stratigraphic data now available.
" 85 Further, Van Nieuwenhuise and Colquhoun (1982b)divided their Rhems Formation into a lower Browns Ferry Member and an upper Perkins Bluff Member.The Browns Ferry (lower)and Perkins Bluff (upper)Members (Fig.v)of the Rhems were considered to grade laterally and vertically into each other.Van Nieuwenhuise and Colquhoun (1982b)also divided the Williamsburg Formation into a lower Bridge Member and an upper Chicora Member.The Lower Bridge Member was also described as grading vertically and laterally, in part, into the overlying Chicora Member.According to Van Nieuwenhuise and Colquhoun (1982b, p.54,): "The Rhems Shale of Sloan (1908)is a distinctive shale containing almost no sand-sized particles and very few calcareous microfossils.
...The type Rhems of Sloan (1908)at Rhems Landing is considered to be the finer-grained end member of the total range of the fine-grained clastics comprising the Browns Ferry Member." and"The lithology of the type Black Mingo Shale of Sloan (1908)is characteristic of a greater portion of the Browns Ferry Member and also the overall Rhems Fonnation than any of the other composite lithologies.
" Van Nieuwenhuise and Colquhoun (1982b)did not fully discuss the lithologies of the Black Mingo formations and their members.They described the Browns Ferry Member, which evidently is the principal concept of their Rhems Formation, as an"arenaceous mud" , clayey sand or, generally, as a silty clay.They (p.54)described the Perkins Bluff Member of the Rhems Formation as an: "...imbricated, pelecypod-rich.
argillaceous sand...resistant, partially silicified Perkins Bluff Member forms a prominent ridge that extends along the Black River and overhangs the Browne Ferry Member several feet near river level." and"The Perkins Bluff Member lithology is considered somewhat variable but throughout maintains agrained texture than the Browns Ferry Member.Parts of the Perkins Bluff member are almost"coquina," such as at its type locality, but grade to an argillaceous sand with numerous pelecypods either as fragments, internal molds, or whole shells." (Van Nieuwenhuise and Colquhoun, 1982b).
Van Nieuwenhuise and Colquhoun (198213, p. 57) described the Williamsburg Formation, or upper Black Mingo, as: "... arenaceous shales, "f&llers earth," and fossilifemus, argillaceous sands of the Lower Bridge Member and the fossiliferous, argillaceous sands and molluscan-rich bioclastic limestones of the Chicora Member.
The Lower Bridge and Chicora members tend to be gradational from the very fine-grained clastics of the Lower Bridge: to the coarse-grained clastics and limestones of the Chicora." and the Lower Bridge Member as: '!..siliceous mudstone and arenaceous shale
..." and '!..fine-grained clastic unit is predominantly clay-size with some silt and occasional clean sand lenses
... Internal molds of pelecypods oriented parallel to bedding planes can be found." Van Nieuwenhuise and Colquhoun, 1982b. Finally, Van Nieuwenhuise and Colquhoun (1982b) described the Chicora Member of the Williamsburg Formation as "... a glauconitic, argillaceous, fossilifemus sand and indurated molluscan-rich limestone
... Within the indurated limestone beds large internal and external molds of Turritella are present along with large valves and fragments of Ostrea sinuosa Rogers and Rogers, ..." In South Carolina, the Ellenton Formation has been recently subdivided into two chronostratigraphic subdivisions, a lower Midwayan (Danian) Ellenton and an upper Sabinian (Thanetian)
Ellenton (Prowell and others, 1985a). This subdivision has resulted in the establishment of a variety of new formations:
Rhems Formation (McClelland (1987), Sawdust Landing Formation and Lang Syne Formation (Fallaw and Price, 1992, 1995); or combinations of the Ellenton Formation with other formations in the Ellenton interval defined by Siple (1967): Ellenton Formation and Rhems Formation (Colquhoun and others; 1983), P1 and P2 (Prowell and others, 1985a, 1985b), Ellenton Formation and Black Mingo Formation
(?), Ellenton Member of the Rhems Formation (Steele, 1985), Ellenton and Wiamsburg Formations (Aadland and others, 1992). Fallaw and Price (1992,1995) abandoned the name Ellenton "because the sediments named by Siple 1967) consist of two different sedimentary sequences with different lithologies deposited during separated cycles of deposition." They recognized two formations in the Ellenton stratigraphic position in the subsurface of the Savannah River area south of Aiken, South Carolina and Augusta, Georgia: the Sawdust Landing Formation and the Lang Syne Formation.
The Sawdust Landing Formation was described by Fallaw and Price (1992, 1995) from the northwestern part of SRS as "... gmy, poorly and moderately sorted, micaceous, silty and clayey quartz sands and pebbly sands with interbedded dark gray clays.
In some wells in the northwestern part of SRS, it consists of yellow, orange, tan, moderately to poorly sorted, micaceous, quartz sands. It is locally feldspathic, and imn sulfides and lignite are common in the darker parts of the section. The clays are fissile in places and contain micaceous silt and fine sand laminae. There appear to be two fining-upward, sand-to-clay sequences in the downdip part of the Site." The Sawdust Landing Formation, as it has been lithologically described, does not occur in Georgia. However, some Sawdust Landing- type sediments are present in the Black Mingo Formation in Burke County, indicating physical correlation with the Sawdust Landing of Price and Fallaw (1992,1995). Most Sawdust Landing lithology is seen in northern Burke County in the basal beds of the Black Mingo. In the Millers Pond core (GGS- 3758) and in the GGS- 3764, the lower part of the Black Mingo Formation consists of coarse, micaceous, poorly sorted, coarse-grained, pebbly sand of Sawdust Landing lithology as described by Fallaw and Price (1992, 1995).
This updip lithofacies of the Lower Paleocene appears to be the downdip extremity of coastal marine/fluvial sediments that are widespread in the subsurface of western South Carolina.
Fallaw and Price (1992, 1995) described the lithology of their Lang Syne Formation in SRS as follows: "At SRS the Lang Syne typically consists of dark gray and black, lignitic clays and poorly and moderately sorted, micaceous, lignitic, muddy quartz sands and pebbly sands. Imn sulfides are common in the darkerparts of the section.
Both sands and clays are glauconitic in places, especially in the Van Nieuwenhuise and Colquhoun (1982b, p.57)described.
the Williamsburg Formation, or upper Black Mingo, as: "...arenaceous shales,"fullers earth," and fossiliferous, argillaceous sands of the UJwer Bridge Member and the fossiliferous, argillaceous sands and molluscan-rich bioclastic limestones of the Chicora Member.The UJwer Bridge and Chicora members tend to be gradational from the very fine-grained clastics of the UJwer Bridge to the coarse-grained clastics and limestones of the Chicora." and the Lower Bridge Member as: "...siliceous mudstone and arenaceous shale..." and"...fine-grained clastic unit is predominantly clay-size with some silt and occasional clean sand lenses...Internal molds of pelecypods oriented parallel to bedding planes can be found." Van Nieuwenhuise and Colquhoun, 1982b.Finally, Van Nieuwenhuise and Colquhoun (1982b)described the Chicora Member of the Williamsburg Formation as"...a glauconitic, argillaceous, fossiliferous sand and indurated molluscan-rich limestone...Within the indurated limestone beds large internal and external molds of Turritella are present along with large valves and fragments of Ostrea sinuosa Rogers and Rogers,..." In South Carolina, the Ellenton Formation has been recently subdivided into two chronostratigraphic subdivisions, a lower Midwayan (Danian)Ellenton and an upper Sabinian (Thanetian)
Ellenton (Prowell and others, 19800).This subdivision has resulted in the establishment of a variety of new formations:
Rhems Formation (McClelland (1987), Sawdust Landing Formation and Lang Syne Formation (Fallaw and Price, 1992, 1995);or combinations of the Ellenton Formation with other formations in the Ellenton interval defined by Siple (1967): Ellenton Formation and Rhems Formation (Colquhoun and others;1983), PI and P2 (Prowell and others, 1985a, 1985b), Ellenton Formation and Black Mingo Formation (?), Ellenton Member of the Rhems Formation (Steele, 1985), Ellenton and Williamsburg Formations (Aadland and others, 1992).Fallaw and Price (1992, 1995)abandoned the name Ellentonbecause the sediments named by Siple 1967)consist of two different 86 sedimentary Sequence8 with different lithologies deposited during separated cycles of deposition.
" They recognized.
two formations in the Ellenton stratigraphic position in the subsurface of the Savannah River area south of Aiken, South Carolina and Augusta, Georgia: the Sawdust Landing Formation and the Lang Syne Formation.
The Sawdust Landing Formation was described by Fallaw and Price (1992, 1995)from the northwestern part of SRS as"...gray, poorly and moderately sorted, micaceous, silty and clayey quartz sands and pebbly sands with interbedded dark gray clays.In some wells in the northwestern part of SRS, it consists of yellow, orange, tan, moderately to poorly sorted, micaceous, quartz sands.It is locally feldspathic, and iron sulfides and lignite are common in the darker parts of the section.The clays are fissile in places and contain micaceous silt and fine sand laminae.There appear to be two fining-upward, sand-to-clay sequences in the downdip part of the Site." The Sawdust Landing Formation, as it has been lithologically described, does not occur in Georgia.However, some Sawdusttype sediments are present in the Black Mingo Formation in Burke County, indicating physical correlation with the Sawdust Landing of Price and Fallaw (1992, 1995).Most Sawdust Landing lithology is seen in northern Burke County in the basal beds of the Black Mingo.In the Millers Pond core (GGS-3758)and in the3764, the lower part of the Black Mingo Formation consists of coarse, micaceous, poorly sorted, coarse-grained, pebbly sand of Sawdust Landing lithology as described by Fallaw and Price (1992, 1995).This updip lithofacies of the Lower Paleocene appears to be the downdip extremity of coastal marine/fluvial sediments that are widespread in the subsurface of western South Carolina.Fallaw and Price (1992, 1995)described the lithology of their Lang Syne Formation in SRS as follows: "At SRS the Lang Syne typically consists of dark gray and black, lignitic clays and poorly and moderately sorted, micaceous, lignitic, muddy quartz sands and pebbly sands.Iron sulfides are common in the darker parts of the section.Both sands and clays are glauconitic in places, especially in the southeastern part of the Site. The basal unit is a greensand in some wells. The clays tend to be fissile and contain micaceous silt and fine sand laminae. Cristobalite is common in some cores. Deposits composed of yellow, omnge, tan, modemtely to poorly sorted, micaceous quartz sands are common in the northwestern part of SRS, with darker, poorly sorted, micaceous facies becoming dominant to the southeast.
In some wells, clean, moderately to well-sorted sands occur near the top of the unit." The Lang Syne Formation of the Fallaw and Price (1992, 1995) in SRS is lithologically more similar to the Black Mingo Formation section in eastern Burke County, than it is to other subdivisions of the formation.
However, according to their description of the unit, their Lang Syne has more clay than the Black Mingo of Burke County, and the sand in the SRS is coarser and more poorly sorted. The principal distinguishing lithic character of the Lang Syne of Sloan (1908) is glauconite, and the Lang Syne of Fallaw and Price (1992, 1995) and the upper part of the Burke County Black Mhgo does contains scattered glauconite.
But there is no consistent Lang Syne lithology in the upper part of the Black Mingo in Burke County. Therefore it is questionable whether the upper part of the undifferentiated Black Mingo Formation in . Burke county is the same as the Lang Syne beds of Sloan (1908) from the type area of the Lang Syne plantation
1.5 miles
east of Fort Moth in Orangeburg County, South Carolina (see Cooke, 1936, for fuller discussion).
Furthermore, the age of the Lang Syne of Fallaw and Price (1992, 1995) is considered to be Late Paleocene (Thanetian or Selandian) (late Midwayan or early Sabinian): "The term "Lung Syne" for the SRS deposits is used here mther than "Rhems'; because of greater lithologic similarity with the type Lange Syne. Our palynological data indicate that the Lung Syne (upper "Elknton'7 strata at SRS and vicinity are Thanetian or Selandian
&her than Dani~n; the Rhems has been dated as Danian Nan Nieuwenhuise and Colquhoun, 1982b)." Palynological dating of the upper part of the Black Mhgo in Burke County indicates that it is mostly Selandian, late Midwayan in age, and not Thanetian (Edwards, personal communication, 1995). Finally, there appears to be a change in tectonism in the vicinity of the Savannah River. The Williamsburg claystone is relative thick in the SRS Ellenton reference core P-18 and in the cores VSC-3 and VSC-4, but is not present a few miles west in Georgia even though the stratigraphic units overlying and underlying the claystone are present and unchanged on either side of the river. Discussion The Ellenton Formation of Siple (1967) consists of two distinct lithostratigraphic units in the Ellenton reference core P-18 from SRS in Aiken County, South Carolina; a lower carbonaceous and lignitic sand unit with virtually the same lithology as the correlative formation in Burke County, and an upper sandy opaline claystone (or mudstone) unit (Williamsburg) (a few inches of the claystone are present in the middle part of the Black Mingo in the core VG-5 in Burke County). The lower sand unit and the claystone unit are also present in the cores VSC-3 and VSC-4 from southern Barnwell and northern Allendale Counties, South Carolina, respectively. Siple (1967) did not identify claystone chips in his type description of the Ellenton.
The lower carbonaceous sand unit is distinct from all named subdivisions of the Black Mingo in that the unit is predominantly a carbonaceous, lignitic, well-sorted, fine-grained sand with some medium-to coarse-grained sand.
Of the named subdivisions of the Black Mingo, the Lang Syne Formation as described by Fallaw and Price (1993, 1995) is most similar to the lower carbonaceous sand unit izi core P-18 and in Burke County. However, the Lang Syne as described by Fallaw and Price (1992, 1995) should be present only in the stratigraphic position of the Williamsburg? claystone rather than underlying the claystone as is the case in the western SRS. We have seen no lithofacies intermediate to the Williamsburg?
claystone and Lang Syne in western South Carolina or in Georgia. Therefore, the stratigraphic position assigned to the Lang Syne by Fallaw and Price southeastern part of the Site.The basal unit is a greensand in some wells.The clays tend to be fissile and contain micaceous silt and fine sand laminae.Cristobalite is common in some cores.Deposits composed of yellow, orange, tan, moderately to poorly sorted, micaceous quartz sands are common in the northwestern part of SRS, with darker, poorly sorted, micaceous facies becoming dominant to the southeast.
In some wells, clean, moderately to well-sorted sands occur near the top of the unit." The Lang Syne Formation of the Fallaw and Price (1992, 1995)in SRS is lithologically more similar to the Black Mingo Formation section in eastern Burke County, than it is to other subdivisions of the formation.
However, according to their description of the unit, their Lang Syne has more clay than the Black Mingo of Burke County, and the sand in the SRS is coarser and more poorly sorted.The principal distinguishing lithic character of the Lang Syne of Sloan (1908)is glauconite, and the Lang Syne of Fallaw and Price (1992, 1995)and the upper part of the Burke County Black Mingo does contains scattered glauconite.
But there is no consistent Lang Syne lithology in the upper part of the Black Mingo in Burke County.Therefore it is questionable whether the upper part of the undifferentiated Black Mingo Formation in Burke county is the same as the Lang Syne beds of Sloan (1908)from the type area of the Lang Syne plantation
1.5 miles
east of Fort Motte in Orangeburg County, South Carolina (see Cooke, 1936, for fuller discussion).
Furthermore, the age of the Lang Syne of Fallaw and Price (1992, 1995)is considered to be Late Paleocene (Thanetian or Selandian)(late Midwayan or early Sabinian): "The termLang Syne" for the SRS deposits is used here rather than because of greater lithologic similarity with the type Lange Syne.Our palynological data indicate that the Lang Syne (upper strata at SRS and vicinity are Thanetian or Selandian rather than Danian;the Rhems has beendatedas Danian (Van Nieuwenhuise and Colquhoun, 1982bJ." Palynological dating of the upper part of the Black Mingo in Burke County indicates that it is mostly Selandian, late Midwayan in age, 87 and not Thanetian (Edwards, personal communication, 1995).Finally, there appears to be a change in tectonism in the vicinity of the Savannah River.The Williamsburg claystone is relative thick in the SRS Ellenton reference core P-18 and in the cores VSC-3 and VSC-4, but is not present a few miles west in Georgia even though the stratigraphic units overlying and underlying the claystone are present and unchanged on either side of the river.Discussion The Ellenton Formation of Siple (1967)consists of two distinct lithostratigraphic units in the Ellenton reference core P-18 from SRS in Aiken County, South Carolina;a lower carbonaceous and lignitic sand unit with virtually the same lithology as the correlative formation in Burke County, and an upper sandy opaline claystone (or mudstone)unit (Williamsburg)(a few inches of the claystone are present in the middle part of the Black Mingo in the core VG-5 in Burke County).The lower sand unit and the claystone unit are also present in the cores VSC-3 and VSC-4 from southern Barnwell and northern Allendale Counties, South Carolina, respectively.
Siple (1967)did not identify claystone chips in his type description of the Ellenton.The lower carbonaceous sand unit is distinct from all named subdivisions of the Black Mingo in that the unit is predominantly a carbonaceous, lignitic, well-sorted, fine-grained sand with some medium-to coarse-grained sand.Of the named subdivisions of the Black Mingo, the Lang Syne Formation as described by Fallaw and Price (1993, 1995)is most similar to the lower carbonaceous sand unitcore P-18 and in Burke County.However, the Lang Syne as described by Fallaw and Price (1992, 1995)should be present only in the stratigraphic position of the Williamsburg?
claystone rather than underlying the claystone as is the case in the western SRS.We have seen no lithofacies intermediate to the Williamsburg?
claystone and Lang Syne in western South Carolina or in Georgia.Therefore, the stratigraphic position assigned to the Lang Syne by Fallaw and Price (1992, 1995) is problematic. On the other hand, the upper part of the undifferentiated Black Mingo Formation in Burke County is alightly more glauconitic than the lower part of the formation, adding credence to the stratigraphic position of the Lange Syne assigned by Fallaw and Price (1992, 1995). Yet, the lower and upper parts of the Black Mingo Formation in Burke County are too similar to subdivide and, in most cores, there is no distinctive bed change that could be cited as a upper/lower Black Mingo boundary.
According to the modern codes of stratigraphic nomenclature (American Commission on Stratigraphic Nomenclature, 1961, 1970; North American Commission on Stratigraphic Nomenclature, 1983), and guides to stratigraphic nomenclature (International Subcommission on Stratigraphic Classification, 19761, if a lithostratigraphic unit is subdivided into two or more lithostratigraphic units, the original name of the unit cannot be restricted to a subdivision of the unit. If the old name is to be retained, then the original lithostratigraphic unit must subdivided into members or the unit be raised in rank to group. Because the siliceous claystone in the upper part of the Ellenton Formation of Siple (1967) has always been a critical lithic component of the Black Mingo, we believe that the name of the siliceous claystone, the Williamsburg Formation, be retained in western SRS. As a result, the name Ellenton cannot be retained unless the Ellenton is raised to group rank, in which case the lower carbonaceous sand must be given a new formation name. Or, the name Ellenton be retained at formation rank, the lower carbonaceous sand be given a new name at member rank, and the Williamsburg dropped in rank in the Savannah River area to a member of the Ellenton Formation.
The later solution is viable according to Article 25 of the North American Stratigraphic Code (1983). The course we choose to take in this report is neither of the above because we currently lack critical data from the SRS. We suggest that the name Ellenton be considered a junior synonym of Black Mingo and the formation in question in Burke County be called undifferentiated Black Mingo Formation.
The formation in question in Burke County is clearly not Sawdust Landing Formation as applied by Fallaw and Price (1992, 1995).
It also is not clearly Rhems lithology of the central South Carolina Coastal Plain. On the other hand, except for its being persistently carbonaceous, the Burke County unit is broadly compatible with Black Mingo lithology.
But, the unit is not consistently divisible into lower and upper lithostratigraphic subdivisions as in the type area of the Black Mingo. According to Edwards (personal communication, 1995), on the other hand, maintains that the Burke County Black Mingo is generally biostratigraphically divisible into lower (Danian) and upper (Selandian) parts. Supportingthe biostratigraphy, there are some scattered instances in Burke County where the Black Mingo does have lower and upper lithostmtigraphic subdivisions.
Out of 15 cores logged in eastern Georgia, we have found 4 inches of Williamsburg-type claystone that is present in the middle part of the Black Mingo at a depth of approximately 410 feet in Bechtel core VG-5. Of the 15 cores, 11 clearly consist of one lithostratigraphic unit. In all of these sections sampled for dinoflagellate biostratigraphy, most were early to middle Midwayan in age with a few samples (from the USGS Girard core) near the top of the formation being of late Midwayan age (Edwards, personal communication, 1995). Therefore we conclude that most of the biostratigraphic evidence indicates that the Black Mingo Formation in eastern Burke County is of early and late Midwayan age (and is correlatable with the Rhems in the type area of the Black Mingo).
In two cores in Burke County the Black Mingo does consist of a lower and upper part. In the core GGS-3757, taken near McBean Creek in northern Burke County, the lower part of the Black Mingo consists of a dark gray to black laminated clay abruptly overlain by an upper glauconitic sand. In the USGS Girard core, the Black Mingo also is divisible into lower and upper parts and the lithostratigraphic divisions are compatible with the Rhems and Williamsburg Formations as described in eastern South Carolina by Van Nieuwenhuise and Colquhoun (198223).
The lower part of the Black Mingo consists mainly of finely sandy clay (1992, 1995)is problematic.
On the other hand, the upper part of the undifferentiated Black Mingo Formation in Burke County is slightly more glauconitic than the lower part of the formation, adding credence to the stratigraphic position of the Lange Syne assigned by Fallaw and Price (1992, 1995).Yet, the lower and upper parts of the Black Mingo Formation in Burke County are too similar to subdivide and, in most cores, there is no distinctive bed change that could be cited as a upper/lower Black Mingo boundary.According to the modern codes of stratigraphic nomenclature (American Commission on Stratigraphic Nomenclature, 1961, 1970;North American Commission on Stratigraphic Nomenclature, 1983), and guides to stratigraphic nomenclature (International Subcommission on Stratigraphic Classification, 1976), if a lithostratigraphic unit is subdivided into two or more lithostratigraphic units, the original name of the unit cannot be restricted to a subdivision of the unit.If the old name is to be retained, then the original lithostratigraphic unit must subdivided into members or the unit be raised in rank togroup.Because the siliceous claystone in the upper part of the EllentonForma.tionof Siple (1967)has always been a critical lithic component of the Black Mingo, we believe that the name of the siliceous claystone, the Williamsburg Formation, be retained in western SM.As a result, the name Ellenton cannot be retained unless the Ellenton is raised to group rank, in which case the lower carbonaceous sand must be given a new formation name.Or, the name Ellenton be retained at formation rank, the lower carbonaceous sand be given a new name at member rank, and the Williamsburg dropped in rank in the Savannah River area to a member of the Ellenton Formation.
The later solution is viable according to Article 25 of the North American Stratigraphic Code (1983).The course we choose to take in this report is neither of the above because we currently lack critical data from the SM.We suggest that the name Ellenton be considered a junior synonym of Black Mingo and the formation in question in Burke County be called undifferentiated Black Mingo Formation.
The 88 formation in question in Burke County is clearly not Sawdust Landing Formation as applied by Fallaw and Price (1992, 1995).It also is not clearly Rhems lithology of the central South Carolina Coastal Plain.On the other hand, except for its being persistently carbonaceous, the Burke County unit is broadly compatible with Black Mingo lithology.
But, the unit is not consistently divisible into lower and upper lithostratigraphic subdivisions as in the type area of the Black Mingo.According to Edwards (personal communication, 1995), on the other hand, maintains that the Burke County Black Mingo is generally biostratigraphically divisible into lower (Danian)and upper (Selandian) parts.Supporting the biostratigraphy, there are some scattered instances in Burke County where the Black Mingo does have lower and upper lithostratigraphic subdivisions.
Out of 15 cores logged in eastern Georgia, we have found 4 inches of Williamsburg-type claystone that is present in the middle part of the Black Mingo at a depth of approximately 410 feet in Bechtel core VG-5.Of the 15 cores, 11 clearly consist of one lithostratigraphic unit.In all of these sections sampled for dinoflagellate biostratigraphy, most were early to middle Midwayan in age with a few samples (from the USGS Girard core)near the top of the formation being of late Midwayan age (Edwards, personal communication, 1995).Therefore we conclude that most of the biostratigraphic evidence indicates that the Black Mingo Formation in eastern Burke County is of early and late Midwayan age (and is correlatable with the Rhems in the type area of the Black Mingo).In two cores in Burke County the Black Mingo does consist of a lower and upper part.In the core GGS-3757, taken near McBean Creek in northern Burke County, the lower part of the Black Mingo consists of a dark gray to black laminated clay abruptly overlain by an upper glauconitic sand.In the USGS Girard core.the Black Mingo also is divisible into lower and upper parts and the lithostratigraphic divisions are compatible with the Rhems and Williamsburg Formations as described in eastern South Carolina by Van Nieuwenhuise and Colquhoun (1982b).The lower part of the Black Mingo consists mainly of finely sandy clay whereas the upper part consists of glauconitic, middle Midwayan) was a muface of calmua aandatone; ghuconitic, calcare0~8 nondeposition (sediment by-pass), or that the sand; and, at the top of the section, a bed of dQ' top of the lawer Black Mingo was eroded. The laminated clay. The lower part of the Blaclr variable thickness of the formations suggests the Mingo was correlated with the Clayton later scenario.
Formation of the eastern Gulf Coaatal Plain and the upper part is in calmua nannofd zone NP 6 (Ectwards, personal co~l~munication, 1996). The upper Midwayan Naheola Formation of the eastern Gulf Coastal Plain occurs in Zone NP 6 (Siesser, 1983). Therefore the glauconitic sand in the upper part of the Black Mingo in the Girard core would be in the upper Midwayan and the lawer part of the Upper Paleocene (lower Thanetian), consistent with a Late Paleocene age as determined by many paleontologiets for the upper Black Mingo. To summarize, our conclusion concerning the stratigraphic position and lithostratigraphy on the "Ellenton" in eastern Burke County is that the name Ellenton is a junior synonym of the name Black Mingo in that lithologies and stratigraphic position of the stratigraphic unit in the Savannah River area are all compatible with the Black Mingo Group of South Carolina.
In addition, the Paleocene (Midwayan and lawer Sabinian) in the Savannah River area in Georgia cannot be assigned to the Clayton Formation, Matthew8 Landing Member of the Clayton, Naheola Formation or Nan& Formation of western Georgia on the baais of lithology.
We do not recognize the Black &go as a group in Burke County because moat of the cored sections consist of only one identifiable lithostratigraphic unit. There is evidence of an upper glauconitic stratigraphic interval in the Black Mingo in Burke County, but ita occurrence appears to be local and shows no systematic pattern of occurrence.
Neither the Rhems Formation nor the Williamaburg Formation are present in eastern Burke County, nor are any of the members of the Rheme and Williamsburg Formations present in Georgia The absence of mappable, Thanetian, upper Black Mingo in eastern Georgia and ib consistent occurrence in South Carolina suglgeets that during the Late Paleocene, either the Georgia coastal area was ~nically stable and the top of the lower Black Mingo (early to whereas the upper part consists of glauconitic, calcareous sandstone; glauconitic, calcareous sand;and, at the top of the section, a bed of silty laminated clay.The lower part of the Black Mingo was correlated with the Clayton Formation of the eastern Gulf Coastal Plain and the upper part is in calcareous nannofossil zone NP 5 (Edwards, personal communication, 1995).The upper Midwayan Naheola Formation of the eastern Gulf Coastal Plain occurs in Zone NP 5 (Siesser, 1983).Therefore the glauconitic sand in the upper part of the Black Mingo in the Girard core would be in the upper Midwayan and the lower part of the Upper Paleocene (lower Thane'tian)
, consistent with a Late Paleocene age as determined by D18D.y paleontologists for the upper Black Mingo.To summarize, our conclusion concerning the stratigraphic position and lithostratigraphy on the"Ellenton" in eastern Burke County is that the name Ellenton is a junior synonym.of the name Black Mingo in that lithologies and stratigraphic position of the stratigraphic unit in the Savannah River area are all compatible with the Black Mingo Group of South Carolina.In addition, the Paleocene (Midwayan and lower Sabinian)in the Savannah River area in Georgia cannot be assigned to the Clayton Formation, Matthews Landing Member of the Clayton, Naheola Formation or Nanafalia Formation of western Georgia on the basis of lithology.
We do not recognize the Black Mingo as a group in Burke County because most of the cored sections consist of only one identifiable lithostratigraphic unit.There is evidence of an upper glauconitic stratigraphic interval in the Black Mingo in Burke County, but its occurrence appears to be local and shows no systematic pattern of occurrence.
Neither the Rhems Formation nor the Williamsburg Formation are present in eastern Burke County, nor are any of the members of the Rhems and Williamsburg Formations present in Georgia.The absence of mappable, Thanetian, upper Black.Mingo in eastern Georgia and its consistent occurrence in South Carolina suggests that during the Late Paleocene, either the Georgia coastal area was tectonically stable and the top of the lower Black Mingo (early to 89 middle Midwayan)was a surface of nondeposition (sediment by-pass), or that the top of the lower Black Mingo was eroded.The variable thickness of the formations suggests the later scenario.
APPENDIX 3 HISTORICAL REVIEW OF CONGAREE FORMATION Sloan (1907, 1908) named the Congaree Formation but did not designate a type locality for the formation.
However, Cooke (1936, p. 59) and Cooke and MacNeil (1952, p. 22) suggested a lectostratotype for the Congaree Formation.
The following discussion of Cooke (1936) and Cooke and MacNeil (1952) concerns the type locality problem for the Congaree Formation in South Carolina: "The type locality of the Congaree shale appears to be on Elmore Williams place at the head of First Creek, 0.8 miles west of Gaston. Sloan reports an &foot ledge of fuller's earth containing numerous large casts of Venericardia
'blanicosta" and shark teeth, overlain by fossiliferous quartzite, exposed on the south side of a large natuml amphitheater.
The fuller's earth is provisionally assigned to the McBean Formation." (Cooke, 1936, p. 69-60) and "Sloan specified no single locality as the type of his Congaree "shale", "sands", or "buhrstone'!
The name is evidently taken from the Congaree River, and it has been suggested (Cooke, 1936, p. 59) that Sloan's locality 505 on the Elmore Williams place at the head of First Creek, a tributary of the Congaree River, be regarded as typical. This locality is dimcult to find without a guide. However, ledges of similar rock are exposed on the road south of Bull Swamp Creek 2+ miles west- northwest of Swansea and also at a waterfall north of the east-west county road about 2+ miles west by north of Swansea" (Cooke and Mdeil, 1952, p. 22). Considering that Cooke (1936) and Cooke and MacNeil (1952) were correct in assigning the exposure in the amphitheater at the head of First Creek at Elmore Williams place, then that would be the principal reference locality for the formation but not by original designation.
The principal reference section Oedostratotype) is the section of Congaree Formation exposed in the amphitheater. The principal reference locality according to Cmke (1936) is in Lexington County, 0.8 mile west of Gaston in the updip central Coastal Plain of South Carolina.
APPENDIX 3 HISTORICAL REVIEW OF CONGAREE FORMATION Sloan (1907, 1908)named the Congaree Formation but did not designate a type locality for the formation.
However, Cooke (1936, p.59)and Cooke and MacNeil (1952, p.22)suggested a lectostratotype for the Congaree Formation.
The following discussion of Cooke (1936)and Cooke and MacNeil (1952)concerns the type locality problpm for the Congaree Formation in South Carolina: "The type locality of the Congaree shale appears to be on Elmore Williams place at the head of First Creek.0.8 miles west of Gaston.Sloan reports an 8-foot ledge offuller's earth containing numerous large casts of Venericardia"planicosta" and shark teeth.overlain by fossiliferous quartzite, exposed on the south side of a large natural amphitheater.
The fuller's earth is provisionally assigned to the McBean Formation." (Cooke, 1936, p.59-60)and"Sloan specified no single locality as the type of his Congaree"shale","sands", or"buhrstone".
The name is evidently taken from the Congaree River, and it has been suggested (Cooke, 1936, p.59)that Sloan's locality 505 on the Elmore Williams place at the head of First Creek, a tributary of the Congaree River, be regarded as typical.This locality is difficult to find witlwut a guide.However, ledges of similar rock are exposed on the road south of Bull Swamp Creekmilesnorthwest of Swansea and*also at a waterfall north of the east-west county road aboutmiles west by north of Swansea." (Cooke and MacNeil, 1952, p.22).Considering that Cooke (1936)and Cooke and MacNeil (1952)were correct in assigning the exposure in the amphitheater at the head of First Creek at Elmore Williams place, then that would be the principal reference locality for the formation but not by original designation.
The principal reference section (lectostratotype) is the section of Congaree Formation exposed in the amphitheater.
The principal reference locality according to Cooke (1936)is in Lexington County, 0.8 mile west of Gaston in the updip central Coastal Plain of South Carolina.90 APPENDIX 4 HISTORICAL REMEW OF THE MCBEAN FORMATION Sl-, 1908, p. 269-273, 459, 460) M referred to the limestone exposed along McBean Creek and at Shell Bluff as Santee Limestone.
Veatch and Stephenson (1911) subsequently abandoned the name Santee, without explanation, for the limestone expmurea at Shell Bluff and McBean Creek in Burke County, Georgia. They referred these exposures to their newly proposed McBean Formation.
Veatch and Stephenson (1911, p. 237- 284) named the McBean Formation for Claibornian deposits in Georgia that they believed were equivalent to the Tallahatta, Lisbon, and possibly lower part of the Gosport Sand of Alabama. The reason they gave for proposing a new formation rather than adopting a previously named formation was that: 'IAlthough in a geneml way the correlatives of these formations
[Tallahatta, Lisbon, and Gosport] may be mgnized in Georgia, the extension of the use of these terms to this State is inappropriate, since the Claiborne group is not natumEly divisible into the same units as in Alabama " Veatch and Stephenson 191 1, p. 236 It is not clear whether they believed that the Alabama formations could not be lithologically dimiminated (divisible) in Georgia, or whether the lithostratigraphic sequence was not the same and, therefore, the application of the Alabama names was inappropriate. However, Veatch and Stephenson (1911) did apply the name McBean Formation generally to siliciclastic, marine deposits they believed to be of Claibornian age across the entire state of Georgia. Although Shearer (1917) and Cooke and Shearer (1918) restricted the McBean to its type area in eastern Georgia, Cooke (1936) subsequently expanded the definition of the unit again to conform to that of Veatch and Stephenson (1911). Later authors, however, recognized only the Lisbon and Tallahatta Formations in western Georgia (MacNeil, 19474 1947b; Herrick, 1961; Toulmin and LaMoreaux, 1963; Herrick and Vorhis, 1963; Owen, 1963, Marsalis and Friddell, 1975; Huddlestun, 1981; Huddlestun and others, 1988). Only Pickering (1970) continued the usage of the name McBean rather than Lisbon for upper Claibornian marine deposits in central Georgia. Herrick (1961) and Herrick and Vorhis (1963), however, extended the name Lisbon Formation to the Savannah River, and Huddlestun, Marsalis, and Pickering (1974) questioned the lithostratigraphic validity of the McBean Formation in central and eastern Georgia Huddlestun (1982) discussed the history of the marine Claibornian and Jacksonian terminology in eastern Georgia and western South Carolina.
Confusion regarding the propriety of the name McBean as opposed to the name Lisbon in Georgia resulted from the original ambiguity of both the type lithostratigmphic concept of the McBean Formation, and the stratigraphy of the type locality of the unit. The only sections cited by Veatch and Stephenson (19ll)(the descriptions of the McBean were taken from notes by T. W. Vaughan) from the type area of the McBean Formation were in ravines and gullies approximately:
... one-quarter of a mile south of McBean Station (Veatch and Stephenson, 191 1, p. 242). The only "ravines and gullies" that are still exposed in that area occur between 0.4 and 0.5 mile (0.66 and 0.8 Ism) southeast to east of the railroad crossing at McBean. The distance given by Veatch and Stephenson (p. 242) as one- quarter mile south of the station would place the "gulliesI'in McBean Creek, and the southern valley wall due south of McBean contains no gullies. However, the precise location of the "gullies" of Veatch and Stephenson (p. 242) is uncertain but appear to be the ravines in the eastern valley wall of McBean Creek approximately
0.6 miles
(0.8 km) southeast to east of the railroad crossing in the community of McBean. At this time, most of these ravines expose only bland Barnwell residuum with rare "nodules", cobbles or boulders of chert. Only the eastern-most ravine still exposes approximately 3 feet (1 m) of McBean (according to the original lithologic descriptions of Veatch and Stephenson, 1911). Based on the lithologic descriptions of APPENDIX 4 HISTORICAL REVIEW OF THE MCBEAN FORMATION Sloan, 1908, p.269-278, 459, 460)first referred to the limestone exposed along McBean Creek and at Shell Bluff as Santee Limestone.
Veatch and Stephenson (1911)subsequently abandoned the name Santee, without explanation, for the limestone exposures at Shell Bluff and McBean Creek in Burke County, Georgia.They referred these exposures to their newly proposed McBean Formation.
Veatch and Stephenson (1911, p.284)named the McBean Formation for Claibornian deposits in Georgia that they believed were equivalent to the Tallahatta, Lisbon, and possibly lower part of the Gosport Sand of Alabama.The reason they gave for proposing a new formation rather than adopting a previously named formation was that: Although in a general way the correlatives of these formations
{Tallahatta, Lisbon, and Gosport]may be recognized in Georgia, the extension of the use of these terms to this State is inappropriate, since the Claiborne group is not naturally divisible into the same units as in Alabama." Veatch and Stephenson 1911, p.236 It is not clear whether they believed that the Alabama formations could not be lithologically discriminated (divisible) in Georgia, or whether the lithostratigraphic sequence was not the same and, therefore, the application of the Alabama names was inappropriate.
However, Veatch and Stephenson (1911)did apply the name McBean Formation generally to siliciclastic, marine deposits they believed to be of Claibornian age across the entire state of Georgia.Although Shearer (1917)and Cooke and Shearer (1918)restricted the McBean to its type area in eastern Georgia, Cooke (1986)SUbsequently expanded the definition of the unit again to conform to that of Veatch and Stephenson (1911).Later authors, however, recognized only the lisbon and TaIlahatta Formations in western Georgia (MacNeil, 19478, 1947b;Herrick, 1961;Toulmin and LaMoreaux, 1963;Herrick and Vorhis, 1963;Owen, 1963;Marsalis and Friddell, 1975;Huddlestun, 1981;Huddlestun and others, 1988).Only Pickering 91 (1970)continued the usage of the name McBean rather than Lisbon for upper Claibornian marine deposits in central Georgia.Herrick (1961)aIid Herrick and Vorhis (1963), however, extended the name Lisbon Formation to the Savannah River, and Huddlestun, Marsalis, and Pickering (1974)questioned the lithostratigraphic validity of the McBean Formation in central and eastern Georgia.Huddlestun (1982)discussed the history of the marine Claibornian and Jacksonian terminology in eastern Georgia and western South Carolina.Confusion regarding the propriety of the name McBean as opposed to the name Lisbon in Georgia resulted from the original ambiguity of both the type lithostratigraphic concept of the McBean Formation, and the stratigraphy of the typelocalityof the unit.The only sections cited by Veatch and Stephenson (1911)(the descriptions of the McBean were taken from notes by T.W.Vaughan)from the type area of the McBean Formation were in ravines and gullies approximately:
...one-quarter of a mile south of McBean Station (Veatch and Stephenson, 1911, p.242).The only"ravines and gullies" that are still exposed in that area occur between 0.4 and 0.5 mile (0.65 and 0.8 kIn)southeast to east of the railroad crossing at McBean.The distance given by Veatch and Stephenson (p.242)asquarter mile south of the station would place the"gullies" in McBean Creek, and the southern valley wall due south of McBean contains no gullies.However, the precise location of the"gullies" of Veatch and Stephenson (p.242)is uncertain but appear to be the ravines in the eastern valley wall of McBean Creek approximately
0.5 miles
(0.8 kIn)southeast to east of the railroad crossing in the community of McBean.At this time, most of these ravines expose only bland Barnwell residuum with rare"nodules", cobbles or boulders of chert.Only the eastern-most ravine still exposes approximately 3 feet (1 m)of McBean (according to the original lithologic descriptions of Veatch and Stephenson, 1911).Based on the lithologic descriptions of Sloan (1908, p. 2701, Veatch and Stephenson (p. 242) and on my own experience in the type area of the McBean, the only lithology that can be clearly attributed to the Claibornian McBean at the type locality is an impure, unconsolidated, mostly massive-bedded, fairly even-textwed, calcarenitic, finely bioclarrtic, finely sandy limestone to very calcareous, calamnitic sand (calcareous marl and soft, chalky limestone of Veatch and Stephenson, 1911). The overlying greenish or drab clays and greenish yellow sands included in the McBean Formation by Veatch and Stephenson (p. 2-42), and which are not presently exposed in the ravines, are more consistent with the lithology of the Dry Branch Formation than with any other lithology known in the McBean. The Dry Branch Formation is exposed at the same elevation as the type McBean, 0.2 mile (0.3 mile south of the junction of Ga. Hwy. 66 and Ga. spur 56) from the McBean type locality.
At the type locality of the McBean, approximately 30 feet (9 m) of soft, yellow to white sand, included in the Barnwell Formation by Veatch and Stephenson (p. 242, section 1, bed 4) and LeGrand and Furcron 1966), and in the McBean Formation by Cooke (1943, p.
661, was assigned to the Irwinton Sand by Herrick and Counts (1968, p. 54). Huddlestun (1982) included this sand section in the Irwinton Member of the Dry Branch Formation on lithologic grounds, soft white sand is not known to occur in the McBean Limestone Member in its type area, but does occur in the Dry Branch Formation.
Bed (e) of Sloan (1908, p. 270) was reported to rest "on irregular surface of (Ow, which is the McBean Limestone Member as we understand it. The "irregular surface" of Sloan (p. 270) may represent the disconforrnity between the McBean and the Dry Branch or a solution horizon at the top of the McBean. Unfortunately, this contact is no longer exposed in outcrop in the type area In the nearby McBean core (GGS-37671, unweathered McBean limestone extends to the top of the Claibornian section where it underlies calcareous sands and limestone of the Utley Limestone Member of the Clinchfield Formation.
Because of physical resemblance, sands and clays immediately overlying the soft limestone of the McBean at the type locality are here included in the Dry Branch Formation.
Finally, The northward projection ofthe Dry Branch/McBean contact from the McBean core (GGS-3537) should be at approximately 20 to 30 feet above the floor of the McBean swamp, consistent with the altitude of the McBean-Barnwell residuum at the McBean type locality.
As an indication of the lithologic distinctiveness of the McBean, Brantley (1916, p. 44-55) presented seven chemical analyses of samples from the McBean Formation along McBean Creek and in the vicinity of Shell Bld on the Savannah River. The percent calcium carbonate in these seven samples ranged from approximately 70% to 8796, compatible with the impure limestone lithology of the presently exposed McBean at the type locality and at Shell Bld. According to Veatch and Stephenson (1911, p. 239) Earle Sloan made a large collection of fossils: I!.. at Sloan's Scarp on McBean Creek, between McBean Station and Savannah River. " Vaughan identified the fauna and presented a faunal list in Veatch and Stephenson (1911, p. 238240) and correlated it with the Lisbon Formation of Alabama, the St. Maurice Formation in Louisiana, and the Cook Mountain of Texas (see Veatch and Stephenson, 1911, p. 240, for the extensive list of fossils between McBean station and Savannah River). The shell bed is signiscant for the concept of the McBean Formation of Veatch and Stephenson (1911) and Cooke and Shearer (1918) as well as many subsequent authors.
Veatch and Stephenson (1911) gave no explanation or precise location for "Sloan's scarp", and it would presumably be the "scarp" mentioned by Sloan (1908) 269-2101 as occurring:
'U.3 miles south of McBean station ... on the south side of McBean Creek...': and exhibiting
'!..a series of deeply incised gullies which expose the lower portion of the... section ...," i.e., the "gullies" mentioned by Veatch and Stephenson (1911, p. 242). Therefore, based on the evidence presented by Sloan (1908) and Veatch and Stephenson (1911), it would appear that the fossil collection reported by Veatch and Stephenson (1911, p. 239-240) came fiom the near vicinity of the type locality of the McBean, Sloan (1908, p.270), Veatch and Stephenson (p.242)and on my own experience in the type area of the McBean, the only lithology that can be clearly attributed to the Claibornian McBean at the type locality is an impure, unconsolidated, mostly massive-bedded, fairly even-textured, calcarenitic, finely bioclastic, finely sandy limestone to very calcareous, calcarenitic sand (calcareous marl and soft, chalky limestone of Veatch and Stephenson, 1911).The overlying greenish or drab clays and greenish yellow sands included in the McBean Formation by Veatch and Stephenson (p.242), and which are not presently exposed in the ravines, are more consistent with the lithology of the Dry Branch Formation than with any other lithology known in the McBean.The Dry Branch Formation is exposed at the same elevation as the type McBean, 0.2 mile (0.3 mile south of the junction of Ga.Hwy.56 and Ga.spur 56)from the McBean type locality.At the type locality of the McBean, approximately 30 feet (9 m)of soft, yellow to white sand, included in the Barnwell Formation by Veatch and Stephenson (p.242, section 1, bed 4)and LeGrand and Fureron 1956), and in the McBean Formation by Cooke (1943, p.56), was assigned to the Irwinton Sand by Herrick and Counts (1968, p.54).Huddlestun (1982)included this sand section in the Irwinton Member of the Dry Branch Formation on lithologic grounds;soft white sand is not known to occur in the McBean Limestone Member in its type area, but does occur in the Dry Branch Formation.
Bed (e)of Sloan (1908, p.270)was reported to rest"on irregular surface of (f)", which is the McBean Limestone Member as we understand it.The"irregular surface" of Sloan (p.270)may represent the disconformity between the McBean and the Dry Branch or a solution horizon at the top of the McBean.Unfortunately, this contact is no longer exposed in outcrop in the type area.In the nearby McBean core (GGS-3757), unweathered McBean limestone extends to the top of the Claibornian section where it underlies calcareous sands and limestone of the Utley Limestone Member of the Clinchfield Formation.
Because of physical resemblance, sands and clays immediately overlying the soft limestone of the McBean at the type locality are here included in 92 the Dry Branch Formation.
Finally, The northward projection of the Dry BranchjMcBean contact from the McBean core (GGS-3537) should be at approximately 20 to 30 feet above the floor of the McBean swamp, consistent with the altitude of the McBean-Barnwell residuum at the McBean type locality.As an indication of the lithologic distinctiveness of the McBean, Brantley (1916, p.44-55)presented seven chemical analyses of samples from the McBean Formation along McBean Creek and in the vicinity of Shell Bluff on the Savannah River.The percent calcium carbonate in these seven samples ranged from approximately 70%to 87%, compatible with the impure limestone lithology of the presently exposed McBean at the type locality and at Shell Bluff.According to Veatch and Stephenson (1911, p.239)Earle Sloan made a large collection of fossils: "...at Sloan's Scarp on McBean Creek, between McBean Station and Savannah River." Vaughan identified the fauna and presented a faunal list in Veatch and Stephenson (1911, p.239-240)and correlated it with the Lisbon Formation of Alabama, the St.Maurice Formation in Louisiana, and the Cook Mountain of Texas (see Veatch and Stephenson, 1911, p.240, for the extensive list of fossils between McBean station and Savannah River).The shell bed is significant for the concept of the McBean Formation of Veatch and Stephenson (1911)and Cooke and Shearer (1918)as well as many subsequent authors.Veatch and Stephenson (1911)gave no explanation or precise location for"Sloan's scarp", and it would presumably be the"scarp" mentioned by Sloan (1908)269-270)as occurring:
"0.3 miles south of McBean station...on the south side of McBean Creek...and exhibiting
"...a serie8 of deeply incised gullie8 which expose the lower portion of the...section...," Le., the"gullies" mentioned by Veatch and Stephenson (1911, p.242).Therefore, based on the evidence presented by Sloan (1908)and Veatch and Stephenson (1911), it would appear that the fossil collection reported by Veatch and Stephenson (1911, p.239-240)came from the near vicinity of the type locality of the McBean, i.e., the soft limeatone or "marln in the lower part of the ddbed sections.
Hawever, neither Sloan (1908) nor Veatch and Stephenson (191 1) mentioned the preaence of richly foeailiferous shelly deposits in their measured sections of the type locality.
In addition, calcitic foesils from the soft limestone in the McBean Member at the type locality and at Shell Bluff are rare, and aragonitic shells are absent. The molluscan assemblage reported by Veatch and Stephenson (1911, p. 239-240) is a diverse, aragonitic, shelly fauna, and has the same delicate shells and preservation as that in the collections of the U.S. National Museum that the senior author examined in 1976. The sediment still adhering to these fossils is not a limestone or finely sandy calcarenite but an olive-gray, argiUaceous, very line sand. Therefore, based on the literature, there is doubt as to the precise location of the shell bed at "Sloan's scarp", and to the precise lithoatraligmphic context of the shell bed. The location given by Veatch and Stephenson (1911, p. 239) "between McBean station and Savannah River" suggests that the source bed of the fossil shells could be exposures along the right bank of McBean Creek below Bennock Millpond at the foot of a steep bluff ("Sloan's scarp?), where McBean Creek passes into the Savannah River flood plain. This interpretation is supported by a comment of Cooke (1936, p. 56) that: The best collection thus far obtained was made by Sloan near the mouth of McBean Creek in Georgia." Based on that comment, the fossil assemblage reported by Veatch and Stephenson (1911) did not come from the type locality of the McBean as it must be understood today (the southern valley wall of McBean Creek from 0.3 to 0.5 mile [0.5 to 0.8 kml southeast of the community of McBean). Rather, the shells appear to have been collected from the lower part of the steep western valley wall of the Savannah River (Sloan's scarp), less than 2 miles (3 km) from the confluence of McBean Creek and the Savannah River. The Bennock Millpond Sand Member crops out in the lower part of this bluff and the McBean Limestone Member crops out in the upper part of the bluff. The McBean ie lithologically the same as the section exposed at Shell Bluff and in the McBean and Millers Pond cores. Therefore, it appears likely that the fossil shell assemblage attributed to the McBean did not come from the McBean Limestone Member as we now know it, but from the underlying Bennock Millpond Sand Member that is correlative with the lower part of the Lisbon Formation in Alabama. This interpretation is consistent with the presence of both aragonitic mollusk shells and fine, well-sorted sand that is characteristic of the sands in the fossil shells in the collections of the U. S. National Museum, and with the very well sorted, fine-grained sand in the lower part of the bluff (Soan's scarp). Currently, the Bennock Millpond Sand Member is largely covered by leaf drift along the face of the bluff but very fine, well-sorted sand with common dark minerals can be seen in small braided rivulet8 from springs and seeps in the lower part of the bluff. Very fine, well-sorted sand with dark minerals is characteristic of the Bennock Millpond Sand Member, not the McBean Limeatone Member. In addition, the structural contour map on the top of the Bennock Millpond Sand Member (Fig. 15) indicates that the top of the formation should be roughly 20 feet (6 m) above the base of the valley wall (Sloan's scarp) or the floor of the Savannah River swamp.
This matches the elevations of the seeps and spring in the bluff and the elevation of the McBean Limestone Member in the upper part of the bluff. Finally, based on drilling, LeGrand and Furcron (1956, p. 33) included an incoherent sand, below ground level at the type locality of the McBean Limeatone Member, in the McBean formation. The incoherent sand is compatible with the Bennock Millpond Sand Member and not with McBean Limestone Member. Because the only distinctive Claibornian lithology present at the type locality of the McBean is the soft, "marly", massive-bedded limestone, then clearly the principle lithostratigraphic concept of the McBean must be that of a sandy limestone.
This is at variance with the correlative upper Claibornian deposits south of the vicinity of Hancock Landing in Burke County and the rest of Georgia where upper Claiborne Group deposits consist of i.e., the soft limestone or"marl" in the lower part of the described sections.However, neither Sloan (1908)nor Veatch and Stephenson (1911)mentioned the presence of richly fossiliferous shelly deposits in their measured sections of the type locality.In addition, calcitic fossils from the soft limestone in the McBean Member at the type locality and at Shell Bluff are rare, and aragonitic shells are absent The molluscan assemblage reported by Veatch and Stephenson (1911, p.239-240)is a diverse, aragonitic, shelly fauna, and has the same delicate shells and preservation as that in the collections of the U.S.National Museum that the senior author examined in 1976.The sediment still adhering to these fossils is not a limestone or finely sandy calcarenite but an olive-gray, argillaceous, very fine sand.Therefore, based on the literature, there is doubt as to the precise location of the shell bed at"Sloan's scarp", and to the precise lithostratigraphic context of the shell bed.The location given by Veatch and Stephenson (1911, p.239)"between McBean station and Savannah River" suggests that the source bed of the fossil shells could be exposures along the right bank of McBean Creek below Bennock Millpond at the foot of a steep bluff ("Sloan's scarp"?), where McBean Creek passes into the Savannah River flood plain.This interpretation is supported by a comment of Cooke (1936, p.56)that: "The best collection thus far obtained was made by Sloan near the mouth of McBean Creek in Georgia.rr Based on that comment, the fossil assemblage reported by Veatch and Stephenson (1911)did not come from the type locality of the McBean as it must be understood today (the southern valley wall of McBean Creek from 0.3 to 0.5 mile[0.5 to 0.8 km]southeast of the community of McBean).Rather, the shells appear to have been collected from the lower part of the steep western valley wall of the Savannah River (Sloan's scarp), less than 2 miles (3 km)from the confluence of McBean Creek and the Savannah River.The Bennock Millpond Sand Member crops out in the lower part of this bluff and the McBean Limestone Member crops out in the upper part of the bluff.The McBean is 93 lithologically the same as the section exposed at Shell Bluff and in the McBean and Millers Pond cores.Therefore, it appears likely that the fossil shell assemblage attributed to the McBean did not come from the McBean Limestone Member as we nowknowit, but from the underlying Bennock Millpond Sand Member that is correlative with the lower part of the Lisbon Formation in Alabama.This interpretation is consistent with the presence of both aragonitic mollusk shells and fine, well-sorted sand that is characteristic of the sands in the fossil shells in the collections of the U.S.National Museum, and with the very well sorted, fine-grained sand in the lower part of the bluff (Sloan's scarp).Currently, the Bennock Millpond Sand Member is largely covered by leaf drift along the face of the bluff but very fine, well-sorted sand with common dark minerals can be seen in small braided rivulets from springs and seeps in the lower part of the bluff.Very fine, well-sorted sand with dark minerals is characteristic of the Bennock Millpond Sand Member, not the McBean Limestone Member.In addition, the structural contour map on the top of the Bennock Millpond Sand Member (Fig.15)indicates that the top of the formation should be roughly 20 feet (6 m)above the base of the valley wall (Sloan's scarp)or the floor of the Savannah River swamp.This matches the elevations of the seeps and springs in the bluff and the elevation of the McBean Limestone Member in the upper part of the bluff.Finally, based on drilling, LeGrand and Furcron (1956, p.33)included an incoherent sand, below ground level at the type locality of the McBean Limestone Member, in the McBean formation.
The incoherent sand is compatible with the Bennock Millpond Sand Member and not with McBean Limestone Member.Because the only distinctive Claibornian lithology present at the type locality of the McBean is the soft,"marly", massive-bedded limestone, then clearly the principle lithostratigraphic concept of the McBean must be that of a sandy limestone.
This is at variance with the correlative upper Claibornian deposits south of the vicinity of Hancock Landing in Burke County and the rest of Georgia where upper Claiborne Group deposits consist of calcareous clay, or very argillaceous limestone
("marl").
Because of the historic confusion in use of the name McBean, and because Sloan (1908) originally referred the limestones along McBean Creek and Shell Bluff to the Santee, Fallaw and Price preferred the name Santee Limestone to that of McBean Limestone in the type area of the McBean. Bmed on lithology, we conclude that there is no Santee Limestone in Georgia, unless it is the sandy limestone at the top of the Still Branch Sand in southern Burke County. We conclude that; 1.) the name McBean be should be changed in lithostratigraphic rank to McBean Limestone Member of the Lisbon Formation.
The charadenstic lithology of the McBean is a sandy limestone; 2.) In this context, the McBean is restricted to the vicinity of McBean Creek, Shell Bluff and the area north of the projected extension of the Pen Branch fault in Burke County; 3.) The name McBean Limestone should not be extended away from the area of its typical development; 4.) the limestone lithology of the McBean is different from the predominantly moldic and indurated Santee Limestone; 5.) the precise bio- stratigraphic correlation of the McBean to the type Santee has not been rigorously established; 6.) there is an updip, calcareous, argillaceous, probably nearshore sand referred to in this report as Bennock Millpond Sand Member, and 7.), it has never been demonstrated that the McBean fossil fauna collected by Sloan is from the McBean Limestone Member of the Lisbon Formation.
It has only been assumed to be from the McBean. calcareous clay, or very argillaceous limestone ("marl").Because of the historic confusion in use of the name McBean, and because Sloan (1908)originally referred the limestones along McBean Creek and Shell Bluff to the Santee, Fallaw and Price preferred the name Santee Limestone to that of McBean Limestone in the type area of the McBean.Based on lithology, we conclude that there is no Santee Limestone in Georgia, unless it is the sandy limestone at the top of the Still Branch Sand in southern Burke County.We conclude that;1.)the name McBean be should be changed in lithostratigraphic rank to McBean Limestone Member of the Lisbon Formation.
The characteristic lithology of the McBean is a sandy limestone; 2.)In this context, the McBean is restricted to the vicinity of McBean Creek, Shell Bluff and the area north of the projected extension of the Pen Branch fault in Burke County;3.)The name McBean Limestone should not be extended away from the area of its typical development; 4.)the limestone lithology of the McBean is different from the predominantly moldic and indurated Santee Limestone; 5.)the precisestratigraphic correlation of the McBean to the type Santee has not been rigorou$ly established; 6.)there is an updip, calcareous, argillaceous, probably nearshore sand referred to in this report as Bennock Millpond Sand Member;and 7.), it has never been demonstrated that the McBean fossil fauna collected by Sloan is from the McBean Limestone Member of the Lisbon Formation.
It bas only been assumed to be from the McBean.94