Safety Analysis Report Intentionally Blank Revision 8-06/14North Anna ISFSI SARRS-1REVISION

Revision 8-06/14 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

Figure 1-1, Figure 1-2, 2.5.1, 2.5.1.5, 2.5.1.5.1, 2.5.1.6, 2.5.1.7, 2.5.1.9, 2.5.4, 2.5.5, 2.5.6 Refs, Figure 2-3, Figure 2-8, Figure 2-9, Figure 2-18 (new), Figure 2-19 (new), Appendix 2A, 4.1, 4.3.2, Figure 4-1, Figure 4-4, 5.1.1.1, 5.4

Update adds description of an alternate transport route to the Independent Spent Fuel storage Installation.4.4.5.4 (new), 4.4.6 Refs

[NAPS-ICR-2012-001]Update added section to reflect the installation of new

seismic instrumentation.Revision 7-06/10 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

9.5[IN 2008-002]Revises description of Notification of Unusual Event to reflect new Emergency Action Level classification for damage to a loaded SSSC confinement boundary.Revision 6-06/08 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

1.1, Figure 1-2

[IN 2006-001]

Describes the addition and lo cation of the second storage pad.2.1.3, 2.1.4, 4.4.1.3

[IN 2008-001]Editorial package.

Revision 8-06/14North Anna ISFSI SARRS-2Revision 5-06/06 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

1.5, 9.1.1, 11.1

[IN 2004-001]

T opical Report DOM-QA-1. The Dominion Nuclear Facility Quality Assurance Pr ogram Description is based on ANSI/ASME NQA-1-1994 and will be maintained as a separate, single document for Dominion facilities.

[10 CFR 50.54(a)]

7.6, 7.7[IN 2004-002]Updated the description of the health physics program to

include dosimetry placed on the ISFSI perimeter fence and clarified the description of the environmental monitoring program.

A.1.1[IN 2003-007]

Deleted the description of the origin al TN-32 cask protective cover design.Revision 4-06/04 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

Figures 2-9 & 4-4[IN 2000-002]Removed the fence and gate symbols incorrectly shown around the service water pump house.

3.1.1, 3.1.1.1, 3.1.1.1.1, 3.1.1.1.2, 3.3.4, 3.3.4.1, 3.3.4.2, 3.3.4.3, 3.3.5, 3.3.7, Tables 3-1 & 3-2, 4.2.3.3, 5.1.2, 5.1.3.1, 5.1.3.4, Tables 5-3 & 5-4, Chapter 6, 7.2.1, 7.2.2, 7.2.3, 7.3.2, 7.3.2.1, 7.3.2.2, 7.3.4, 7.4, 7.4.1, 7.5, Tables 7-1, 7-2, 7-3, 7-4, 7-5, 7-6, 7-7, 7-8, 7-9, 7-10, 7-11, 7-12, 7-13, 7-14, 7-15, & 7-16, Figures 7-2, 7-3, 7-4, & 7-5, 8.2.10.2, 8.2.10.3, 8.2.11, Table 8-1, 9.1.1.4, 9.1.4, Table 10-2, A.1.1, A.1.2, A.1.3, A.1.3.1, A.1.4, A.1.8, A.1.8.1, A.1.9, A.1.10, Tables A.1-1, A.1-2, & A.1-3, Figures A.1-1, A.1-2, A.1-3, &

A.1-4[IN 2002-002 & IN 2 003-002]Updated the shielding, critical ity , thermal, and accident evaluations associated with the increased initial enrichment of 4.30 weight percent U 235 and the increased assembly average burnup of 45,000 MWD/MTU. [10 CFR 72.56 License Amendment]

Revision 8-06/14North Anna ISFSI SARRS-3 4.1, 7.1.1, 7.1.2, 7.3.1, 7.4, Figure 7-1[IN 2003-001]Added locked security pers onnel access gates to the ISFSI perimeter fence.

4.4.1.2, Figure 4-14[IN 2003-005]Placed a cask pedestal in the cask loading area of the

spent fuel storage pool.

4.4.5.3, 5.2

[IN 2003-006]Revised organizational titl e of the Shift Manager

.11.1

[IN 2003-004]

[IN 2002-004]Identified the analyses in Chapters 4 & 6 of the TN-32 FSAR, Rev. 0, that were added to the North Anna ISFSI SAR.A.1.1[IN 2002-005]Provided bolt torque ranges for the TN-32 casks.

and fabricated to TN-32 Final Safety Analysis Report, Revision 0.A.1.1, Appendix A.1 Attachment 4[IN 2002-006]

Incorporated additional anal yses re garding TN-32 cask gap between center basket rails.

A.1.2[IN 2003-003]Added allowance for the storag e of a fuel assembly with rod clips.Revision 3-06/02 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

4.4.5.1, 8.2.5.1

[IN 2001-001]Clarified the description of the placement of fire extinguishers at the ISFSI site as well as the availability of fire fighting equipment and personnel.

5.1.1.1[IN 2001-005]

Changed cask receipt proce dure consistent with the North Anna Power Station Updated Final Safety Analysis Report.9.2.2.1[IN 2002-001]Deleted incorrect testing re quirements for electrical and communications systems.Revision 4-06/04 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

Revision 8-06/14North Anna ISFSI SARRS-4 A.1.1, Appendix A.1 Attachment 1[IN 2001-003]Incorporated the modified TN-32 cask lid bolt analysis.

A.1.1, Appendix A.1 Attachment 3[IN 2001-002]Modified the TN-32 cas k protective cover and overpressure system.

A.1.7, Appendix A.1 Attachment 2[IN 2000-001]

Incorporated structural anal yses for missile impacts on TN-32 casks.Revision 2 Section ChangesMade under the provisions of 10 CFR 72.48 except where indicated in brackets.

3.1.1, A.1.2

[IN 99-01]Added information on the storage of burnable poison rod

FigurePageFigure 4-11Overturning Factors of Safety. . . . . . . . . . . . . . . . . . . . . . . . . . . . .4-36Figure 4-12Transporter Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4-37 Figure 4-13Fuel and Decontamination Buildings Plan View . . . . . . . . . . . . . .4-38Figure 4-14Fuel and Decontamination Buildings Side View . . . . . . . . . . . . . .4-39Figure 5-1Plan and Profile of ISFSI Site Access Road . . . . . . . . . . . . . . . . . .5-8Figure 7-1ISFSI Layout. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7-15Figure 7-2Dose Rate for 84 Base Case Casks Versus Distance. . . . . . . . . . . .7-16Figure A.1-1TN-32 Surface Dose Rate Measurement Locations . . . . . . . . . . . .A.1-23 Figure 3C.3-14Finite Element Model - Bottom Support Rail. . . . . . . . . . . . . . . . .A.1 Att. 4-9Figure 3C.3-15Finite Element Model - Loading and Boundary Conditions. . . . . .A.1 Att. 4-10Figure 3C.3-16Finite Element Model - Deformed Shape, 0.24" Distance . . . . . . .A.1 Att. 4-11Figure 3C.3-17Finite Element Model - Deformed Shape, 0.5663" Distance . . . . .A.1 Att. 4-12Figure 3C.3-18Finite Element Model - Deformed Shape, 0.0" Distance . . . . . . . .A.1 Att. 4-13 Revision 8-06/14 North Anna ISFSI SAR x Intentionally Blank Revision 8-06/14 North Anna ISFSI SAR LEP-1Table of ContentsFirst PageLast PageRevision i xRevision 8-06/14List of Effective PagesFirst PageLast PageRevision LEP-1 LEP-2Revision 8-06/14 Chapter 1 First PageLast PageRevision 1-1 1-6Revision 8-06/14 Chapter 2 First PageLast PageRevision 2-1 2-64Revision 8-06/14 2A-i 2A-iiRevision 8-06/14 2A-1 2A-44Revision 8-06/14 2B-i 2B-iiRevision 8-06/14 2B-1 2B-72Revision 8-06/14 Chapter 3 First PageLast PageRevision 3-1 3-10Revision 8-06/14 Chapter 4 First PageLast PageRevision 4-1 4-40Revision 8-06/14 Chapter 5 First PageLast PageRevision 5-1 5-8Revision 8-06/14 Chapter 6 First PageLast PageRevision 6-1 6-2Revision 8-06/14 Chapter 7 First PageLast PageRevision 7-1 7-16Revision 8-06/14LIST OF EFFECTIVE PAGES Revision 8-06/14 North Anna ISFSI SAR LEP-2LIST OF EFFECTIVE PAGES (CONTINUED)

Chapter 8 First PageLast PageRevision 8-1 8-8Revision 8-06/14 Chapter 9 First PageLast PageRevision 9-1 9-6Revision 8-06/14 Chapter 10 First PageLast PageRevision 10-1 10-4Revision 8-06/14 Chapter 11 First PageLast PageRevision 11-1 11-2Revision 8-06/14Appendix A First PageLast PageRevision A-1 A-2Revision 8-06/14 A.1-1 A.1-24Revision 8-06/14 A.1 Att. 1-1 A.1 Att. 1-22Revision 8-06/14 A.1 Att. 2-1 A.1 Att. 2-6Revision 8-06/14 A.1 Att. 3-1 A.1 Att. 3-6Revision 8-06/14 A.1 Att. 4-1 A.1 Att. 4-14Revision 8-06/14 Revision 8-06/14 North Anna ISFSI SAR 1-1Chapter 1INTRODUCTION AND GENERAL DESCRIPTION OF STORAGE SYSTEM

Discharged spent fuel asse mblies from the North Anna Power Station, Units 1 and 2 are currently stored in a sp ent fuel pool common to bo th Units. The spent fuel pool provides for interim storage of 1737 fuel assemblies in high density storage racks. Typically, 64 spent fuel assemblies are dischar ged from each Unit about every 18 months. Section 3.1.1 provides a description of the spent fuel. Additional information on the fuel design is available in Section 4.2 of the North Anna Power Station Updated Final Safety Analysis Report (UFSAR).Based on the current fuel management strategy and refueling outage schedule, the spent fuel pool will lose the capacity for si ngle unit full core di schar ge in late 1998. St orage capacity in the pool will be completely exhauste d in 2000, therefore, additional spent fuel storage capacity is needed. To support this need, sealed surface storage casks (SSSCs) have been chosen for use at an Independent Spent Fuel Storage Installation (ISFSI) at the North Anna site.

The North Anna ISFSI is designed to st ore all the anticipated spen t fuel resulting from the operation of the North Anna Power Station Units 1 and 2 in excess of that which can be stored in the spent fuel pool, or approximately 1824 fuel assemblies. Construction of the North Anna ISFSI is scheduled to be gin in June 1997 and the first SSSC should be placed at the ISFSI in August 1998.The North Anna ISFSI is located within the site boundary of the North Anna Power Station, which is owned 88.4% by Virginia Electric and Power Company (Virginia Power) and 11.6% by the Old Dominion Electric Cooperative. Virginia Power is respon sible for operations at the Station.This SAR is primarily directed towards analyzing the sa fety aspects of SSSC handling and storage once the SSSCs have been lifted by the cask transporter, and how the safety requirements in 10 CFR 72 are satisfied. Handling of th e SSSCs inside the Fuel a nd Decontamination Buildings and cask crane bay is performed in accordan ce with the operating license for the North Anna Po wer Station under 10 CFR 50, however, these operations are also described in this SAR.

This SAR indicates that up to th ree concrete storage pads could be used at the North Anna ISFSI and were intended to stor e vertical, metal SSSCs. An addi tional pad, to be used under a 10 CFR 72, Subpart L general license, wa s installed in place of the original Pad 2. The ISFSI site plans described in this SAR have been updated to reflect the new configuration of the ISFSI site with this additional pad.

Revision 8-06/14 North Anna ISFSI SAR 1-2 1.2 GENERAL The North Anna site comprises approximately 1043 acres in Louisa County, Virginia. The ISFSI is located near the cente r of the site, approximately 2000 feet southwest of the protected area for North Anna Units 1 and 2. Figure 1-1 shows a general layout of the North Anna site.

North Anna Power Station Units 1 and 2 consist of two closed-cycle pressurized water reactors (PWR) provided by Westinghouse. Operating licenses were issued by the NRC in April 1978 and August 1980 for Units 1 and 2, respectively. Unit 1 started commercial operation in June 1978 and Unit 2 in December 1980. A complete description of the po wer station is provided in the North Anna Power Station UFSAR, NRC dockets 50-338/339.

The North Anna ISFSI consists of th ree concrete storage pads on which the loaded SSSCs are placed. The storage pads will be built in sequence, as needed, and in an order which minimizes radiation exposures. The storage pads will be su rrounded by a security fenc e and a nuisance fence.

===1.3 GENERAL===

STORAGE SYSTEM DESCRIPTION The North Anna ISFSI uses SSSCs to store fuel irradiated at the North Anna Power Station.

Typically, the SSSCs are large cylindrical vessels capable of storing up to 32 unconsolidated PWR fuel assemblies. The SSSCs are made of carbon steel, stai nless steel, or cast iron. The y are about 16 feet long and 8 feet in diameter, have walls severa l inches thick and weigh 100 to 125 tons fully loaded. The fuel is stored in a helium at mosphere and held in place by a bask et or rack.

Figure 1-2 shows the general arrangement of the North Anna ISFSI.The loading and preparation of an SSSC take s place within the Fuel and Decontamination Buildings of the North Anna Power Station. The SSSC is lo aded under water in the spent fuel pool where a lid is positi oned on the SSSC prior to lifting it out of the water. Water in the SSSC is removed, the interior is further dried under vacuum and then filled with helium. Following decontamination of the outer surface, the SSSC is placed in a transporter outside the Decontamination Building. The SSSC is then transferred to the ISFSI, where it is emplaced on one of the three storage pads.The SSSCs are totally passive sy stems, with natural convec tion cooling sufficient to maintain safe fuel clad temperatures. The SSSC walls prov ide adequate shielding, and no radioactive products are released under any credible conditions.

===1.4 IDENTIFICATION===

OF AG ENTS AND CONTRACTORS SSSCs to be used in the North Anna ISFSI are designed and fabricated by other organizations and will be purchased by Virginia Power. The SSSC supplie rs are responsible for SSSC fabrication, testing, and delineation of specific SSSC requirements, if any. Information Revision 8-06/14 North Anna ISFSI SAR 1-3related to the qualifications of the SSSC suppliers is contained in the T opical Safety Analysis Reports referenced in Section 1.5.Site preparation and necessary construction will be performed by Virginia Power's Site Services Department, using spec ialty subcontractors, as required.

===1.5 MATERIAL===

INCORPORA TED BY REFERENCE Detailed information describing the SSSCs is provided in the SSSC Topical Safety Analysis Reports referenc ed in Appendix A, Table A-1 of this Safety Analysis Report (SAR). General references to the SSSC Topical Sa fety Analysis Reports are made in sections of this SAR, as needed, to supplement information contained in the SAR. Ea ch SSS C type is described in a sub-appendix of Appendix A. Also, the sub-appendices provid e SSSC-specific information not contained in the SSSC Topical Safety Analysis Reports. The combination of this SAR, including appendices, and an y one of the re ports describing the SSSCs (one per type of SSSC) provides all the information described in Regulatory Guide 3.62 (February 1989), Standard Format and Content for the Safety Analysis Report for Onsite Storage of Spent Fuel Storage Casks.The following documents, which are already on f ile with the NRC, are referenced throughout this SAR:

1.North Anna Power Station Units 1 and 2, Updated Final Safety Analysis Report, NRC dockets 50-338 and 50-339.2.North Anna Power Station Units 1, 2, 3 and 4, Environmental Report, submitted March 15, 1972.3.North Anna Power Station, Emergency Plan

.4.Dominion Nuclear Facility Quality As surance Program Description, T opical Report DOM-QA-1.5.Surry Power Station, Independent Spent Fuel Storage Installation, Safety Analysis Report

.  

Revision 8-06/14 North Anna ISFSI SAR 1-5 Figure 1-2 ISFSI GENERAL ARRANGEMENT Revision 8-06/14 North Anna ISFSI SAR 1-6 Intentionally Blank Revision 8-06/14 North Anna ISFSI SAR 2-1Chapter 2SITE CHARACTERISTICS

===2.1 GEOGRAPHY===

AND DEMOGR APHY OF SITE SELECTED 2.1.1 Site Location The location of the Independent Spent Fuel Storag e Installation (ISFSI) is approximately 2000 feet southwest of the North Anna Power Station Units 1 and 2 protected area and within the boundaries of the North Anna site (see Figure 1-1). The ISFSI occupies approximately 11 acres.The North Anna site is located in the north-centra l portion of Virginia in Louisa County.

The site is on a peninsula on th e southern shore of Lake Anna at the end of State Route 700. The earth dam that creates the lake is approxima tely 5 miles southeast of the site. The North Anna River flows southeasterly, joining the South Anna River to form the Pamunkey River approximately 27 miles southeast of the site.The largest community within 10 miles of the site is the Town of Mineral (Louisa County), which had a 1990 population of 452 persons, and is approximately 6 miles west-southwest of the site. The community of Louisa, which had a 1990 population of 1088 persons, is approximately 12 miles to the west of the site.

Figure 2-1 shows the general location of the site and the surrounding localities within 10 miles.Regionally, as indicated in Figure 2-2 , the site is approximately 40 miles north-northwest of Richmond; 36 miles east of Charlottesville; 22 miles southwest of Fredericksburg; and 70 miles southwest of Washington, D.C. Interstate highways 95 and 64, the two principal highways serving Richmond, pass within 16 miles east and 16 miles southwest of the site, respectively.

The approximate coordinates of the ISFSI are:

Latitude-LongitudeUniversal Transverse Mercator 38° 3.8' N - 77° 47.5' W 4,215,900 mN - 255,100 mE; Zone 18S 2.1.2 Site Description The North Anna site property comprises 1803 acres, of which approximately 760 acres are covered by water. The site boundary is shown in Figure 2-3. Virginia Power owns, in fee simple, all of the land within the site boundary, both above and beneath the surfaces, including those portions of the reservoir and waste heat treatment facilities (cooling lagoons) that lie within the site boundary. The controlled area is all of the area within the site boundary. Virginia Power also owns, in fee simple, all land outside the site boundary that forms the reservoir and the cooling lagoons up to their expected high-water marks. The Station and all supporting facilities including the reservoir, cooling lagoons, earthen dam, dikes, railroad spur, and roads constitute approximately 13,775 acres.The site plan for the North Anna ISFSI and its relati ve location to the North Anna Power Station are presented on Figure 2-3. Consistent with Section 2.1.2.1 of the North Anna Power Revision 8-06/14 North Anna ISFSI SAR 2-2 Station UFSAR, the restricted area for the ISFSI is the North Anna site boundary. The controlled area boundary is also the site boundary. As shown on Figure 2-3 , the minimum distance to the controlled area boundary from th e ISFSI is approximately 2500 feet and occurs in the southwest sector relative to the ISFSI.Since the controlled area for the North Anna ISFSI is wholly with in the property lines for the North Anna site, Virginia Power has full author ity to determin e all activities including the exclusion and the removal of personnel and property. No activities unrelated to operation of the North Anna Power Station or the ISFSI are pe rmitted within the controlled area.The topography in the site region is character istic of the central Pi edmont Plateau with a gently undulating surf ace varying from 200 to 500 feet above sea level (see Figure 2-7). The surrounding region is covered with forest and brushw ood interspersed with an occasional farm. The land adjacent to the reservoir is becoming in creasingly residential as the land is developed.

Figure 2-8 shows the topography in the vicinity of the ISFSI. Drainage of surface water at the ISFSI will be provided by channels to a small creek to the south and west. The area inside the IS FSI perimeter fence will be graded level. Areas not needed for ISFSI operations will be seeded with grass, while areas needed for ISFSI operations will be covered with course gravel. The areas surrounding the west, south and east sides of the ISFSI perimete r fence will remain forested. Based on this description, the potential for erosion at the ISFSI is small, and the potential for forest fires exists only outside the ISFSI perimeter fence.

====2.1.3 Population====

Distribution and TrendsCities within 50 miles of the site are shown on Figure 2-2. Section 2.1.2 of the North Anna ISFSI Environmental Report, contained in the ISFSI Reference Document Manual, provides detailed information on population projections.

2.1.4 Use Of Nearby Land and Waters The North Anna site is located in a predominantly rural area of L ouisa County, Virginia. In Louisa County and the four adjacent counties of Spotsylvania, Orange, Hanover and Caroline, an average 42.5% of the total county acreage is used fo r agriculture.

Approximately 38% of the 508,443 agricultural acres in these five counties is cropland, 15% is pastureland, and the balance is woodland. Principal crops are barley, tobacco, corn, wheat, hay and soybeans. Poultry, livestock and dairy products are also major agricultural products of the area and represent the greatest share of the area's cash farm income.

Section 2.1.2.3 of the North Anna ISFSI Environmental Report, contained in the ISFSI Reference Document Manual, provides information on recreational activities on Lake Anna. Section 2.2.1 that follows provides informati on on industrial acti vities in the area.

Revision 8-06/14 North Anna ISFSI SAR 2-3 2.2 NEARBY INDUSTRIAL, TRANSPORTATI ON, AND MILITARY F ACILITIES 2.2.1 DescriptionCurrently, there are none of the following facilities within 5 miles of the North Anna site:

military bases, manuf acturing plants, chemical plants and storage facilities, airports, major railroad lines, major water transportation routes or oil and gas pipelines.

Also, there are no mining activities within 5 miles of the site.There are no significant indu strial acti vities within 5 miles of the site. Based on trends of industrial growth and projected population figures, it is not expected that any major i ndustrial expansion will occur in this area.

Roads within 10 miles of the site are shown on Figure 2-1. Virginia Route 208 and US Route 522 are the major transportation routes serving the site area th at pass within 5 miles of the site, however, there are no specific data on the types and qua ntities of products and materials transported on these roads.

State Route 700, east from State Route 652, is the only land access to the North Anna site. It ends at the site west boundary. No chemicals or cargo are expect ed to be transported on this portion of Route 700 unless the chemicals or cargo are used by the North Anna Power Station.

The railroad line closest to the site is the line owned by CSXT. It passes through the towns of Louisa, Mineral, Fredericks Hall and Bumpass; its closest approach to the site is approximately

===5.5 miles===

southwest. A spur line conn ects the site with this line.There are only two airports within 10 miles of the site: Lake A nna (Rest-A-While) Airport and Cub Field. The Louisa County Airport is located 11 miles west-southwest of the site. Operations at these airports involve light aircraft. None of these airports are expected to grow significantly in the foreseeable future. Section 2.2.1.6.2 of the North Anna Power Station UFSAR includes a discussion of airways over the site.

====2.2.2 Effects====

of Potential AccidentsThe only sources of explosion and formation of flammable vapor clouds are explosive materials/chemicals carried by truck traffic.The largest possible explosive load routinely transported contains 8500 gallons of gasoline (set by highway weight limits). Based on an analysis in Section 2.2.2.1.1 of the North Anna Power Station UFSAR, if this amount of gasoline were to e xplode at the closes t point to the site, 1.5 miles on State Route 652, a peak overpressure of 1 psi would be experienced approximately 1900 feet away from the point of explosion. The overpressure experienced by the SSSCs 1.5 miles away from the explosion would be significantly less than 1 psi.

Revision 8-06/14 North Anna ISFSI SAR 2-4 2.3 METEOROLOGY Meteorology at the North Anna Power Station is described in Section 2.3 of the North Anna Power Station UFSAR. Information from the UF SAR concerning meteorol ogy is summarized and supplemented below.2.3.1 Regional Climatology The climate of the site is basically modified continental. The summers are warm and humid while winters are generally mild.

The Blue Ridge Mountains to the west act as partial barriers to winter storms, modifying their intensity as they move across the rolling Piedmont to the Tidewater region adjacent to the Atlantic Ocean.

Climatic characteristic s are illustrated in Figure 2-4 through Figure 2-6 which show daily average temperatures, daily extreme temperatures, and the probabili ty of an extreme l-mile wind passage for Richmond, Virginia. Temperatures in the site region rarely exceed 95°F or fall below 10°F.Rainfall averages approximately 44 inches per year around the site region and is fairly well distributed throughout the year, with the exception of the m onths of July and August, when thunderstorm activity raises the mo nthly totals to approximately 5 inches. Tropical storms may also contribute significantly to precipitation during the late summer and fall. Records indicate that the maximum rainfall during a 24-hour period was 8.79 inches, which occurred in August 1955.Snowfalls of 4 inches or more occur an average of on ce per year. Snow us ually only remains on the ground from 1 to 4 days at a time. Richmond averages 14.6 inches of snow per year.Tornadoes are infrequent in Virginia. In the period from 1916 through 1987, only 65 tornadoes were reported within a 50-mile radius of the North Anna site (Reference 1). This averages to less than one tornado per year with in this radius. Based on statistical methods proposed by Thom (Reference 2) and as described in detail in Section 2.3.1.3.2 of the North Anna Power Station UFSAR, the probability of a torna do striking a point within the 50-mile radius is 3.25 x 10-5 per year, or a recurrence interval of 30,800 years.Richmond averages 37 thunderstorm days per year with a quarter of th ese typically occurring in July. Cloud-to-ground lightning strike data within an approximate 10-kilometer radius of the site region was an alyzed for the ten year period of 1984 to 1993. Results indicate a minimum yearly strike frequency of 1.1 strikes per square kilomete r in 1992 and a maximum yearly strike frequency of 3.9 strikes per square kilometer in 1988.

Meteorology 2.3.2.1 Data Sources Meteorology in the North Anna Power Station site area wa s evaluated as part of its Operating License application review. Data acquired by the National Weather Service and Revision 8-06/14 North Anna ISFSI SAR 2-5summarized by the Environm ental Data Service (Reference 3) were used to determine the normals, means, and extremes of temperature and precipitation appl icable to the North Anna site re gion.Temperature extremes for Rich mond, Virginia are shown in Figure 2-5. In August 1918 a record high of 107°F was recorded and in January 1940 a record low of -12°F was recorded. The extreme temperatures used as the design criteria for the SSSCs, -20°F and 115°F, were selected because they exceed the recorded temperature extremes.The design solar insolation values for casks stored at the ISFSI are adapted from 10 CFR 71.71(c). The insolation values are 800 gm-cal/cm2 for fl at surf aces and 400 m-cal/cm2 for curved surfaces applied over a 12-hour daylight period. These insolation values may be averaged over a 24-hour period fo r long-term thermal analyses.Joint frequency distributions of wind speed and horizontal atmospheric stability for both the lower and upper tower levels are presented in Tables 2.3-9 and 2.3-10 of the North Anna Power Station UFSAR. In addition, th e joint frequency distribution of lower level wind speed and vertical atmospheric st ability are presented in Table 2.3-11 of the North Anna Power Station UFSAR. The distributions are for Stability Classes A through G as defined in Regulatory Guide 1.23.2.3.2.2 Topography The North Anna Power Station site and exclusi on area consist of approximately 1043 acres located in the north-central port ion of Virginia in Louisa County beside Lake Anna. The site region is characterized by gently rolling terrain that rises to an average height of 50 to 150 feet above Lake Anna and is cut by the North Anna River. The topography in the site re gion is characteristic of the Ce ntral Piedmont Plateau, wh ich has a gently undulating surface that varies from 200 to 500 feet above sea level.

Figure 2.3-24 of the North Anna Power Station UFSAR is a map showing detailed topographic features with in an 8-kilometer (5 mile) radius centered on the site area.

Meteorological Measurement Program The North Anna Power Station will al so pro vide meteorological monitoring for the ISFSI.

A detailed description of th e meteorological monitoring program is provided in Section 2.3.3 of the North Anna Power Station UFSAR. Data from this program, however, w ill not be used to estimate offsite concentrations of airborne effluents from the ISFSI, as no credible mechanism for the release of airborne ef fluents has been postulated.As illustrated in Figure 2.3-25 of the North Anna Power Station UF SAR, the ISFSI is located approximately 3500 feet from the primary meteorologic al tower, with the service water reservoir and the Units 1 and 2 discharge canal between the ISFSI and the tower. Based on the analysis in Section 2.3.3.6 of the Surry Power Station ISFS I SAR, the separation between the Revision 8-06/14 North Anna ISFSI SAR 2-6North Anna ISFSI and the meteorological tower, an d the intervening topography and other heat sources, no effect is expected on the tower fro m the heat source represented by a fully loaded ISFSI.2.3.4 Diffusion Estimates 2.3.4.1 Basis No routine or accidental releases are planned or postulated as a result of ISFSI operation.

Nevertheless, /Q values have been calculated which can be used to estimat e radiological doses from the accidental release analyzed in Section 8.2.10.2.3.4.2 CalculationsFive years of meteorological data from 1989 through 1993 were used to calculate dispersion f actors (/Q) for use in the dose assessment of accident airborne releases. Wind speed, direction, distance from the ISFSI to the North Anna Power Station site boundary , and atmosphe ric stability class (based on the temperatur e gradient determined from instrumentation at the 10 meter and the 158.9 foot elevations) serve as inputs to the dispersion model desc ribed in Re gulatory Guide 1.145 (Reference 4).Table 2-1 provides the /Q values at the site boundary fo r an instantaneous accidental release from the ISFSI. Time-dependent /Q values are not provided since routine releases are neither planned nor anticipated. The /Q values provided in Table 2-1 represent the most limiting /Q values to members of the public with the SE sector having the greatest /Q at 1100 meters from the ISFSI to the site boundary. According to the dispersion mo del, the topographical features surrounding the North Anna site are such that the /Q v alues monotonically decrease with distance from the site boundary. Therefore, the li miting dose to members of the public will occur at the site boundary in the SE sector and dose to members of the public will decrease as the distance from the s ite boundary increases.

2.3.5 References1.Storm Data, National Oceani c and Atmospheric Administra tion, National W eather Records Center, Environmental Data Service, Asheville, North Carolina.2.H. C. S. Thom, "Tornado Probabilities,"

Monthly Weather Review, Vol. 91, Nos. 10-12, pp. 730-736.3.Richmond, Virginia 1987 Local Climatologica l Data, Annual Summary With Comparative Data, National Oceanic and Atmospheric Administration, National Weather Records Center, Environmental Data Service, Asheville, North Carolina.4.U. S. NRC Regulatory Guide 1.145, Atmospheric Dispersion Models for Post Accident Consequence Assessments at Nuclear Power Plants, Revision 1, November 1982, Reissued February 1983.

Revision 8-06/14 North Anna ISFSI SAR 2-7 2.4 HYDROLOGY The data and analys es in this section were obtaine d from the material presented in Section 2.4 of the North Anna Power Station UFSAR (References 1 & 2). In addition, hydrologic data for the period from 1971 to 1993 were also reviewed. No severe event occurred from 1973 to the present which exceeded the maximum flood on record that has occurred on the North Anna River. The subsurface hydrology section includes site specific data produced as a result of the ISFSI site soils investigation, and follow-up monitoring.

====2.4.1 Hydrologic====

Description 2.4.1.1 Site and StructuresThe general site grade for th e ISFSI is at Elevation 311 feet msl. This grade varies some what to permit proper drainage. The top elevation of the storage pads will be at 311.5 feet msl. Areas outside of the ISFSI generally sl ope to the south, towards Lake Anna. There is an ISFSI access road to the west of the ISFSI which is graded from Elevation 332 feet msl to Elevation 311 feet msl into the site. Site grade is above the probable maximum flood level, as discussed in Section 2.4.2.2. There are no above-ground enclosed structures associated with this facility.2.4.1.2 HydrosphereRegional topography and char acteristics are shown on Figure 2-7. The region surrounding the North Anna Power Station site is characterized by ge ntly rolling terrain that rises to an average height of 50 to 150 feet above Lake Anna and is bisected by the North Anna River. The topography in the site re gion is characteristic of the Central Pied mont Plateau, which has a gently undulating surface that varies from 200 to 500 feet above sea level.An earth dam approximately five miles southeast of the site forms Lake Anna, which extends approximately 17 miles along the old North Anna river bed. The lake and waste heat treatment facility cover a surface area of 13,000 acres and contain approximately 100 billion gallons of water.The ISFSI site is located more than 60 feet above normal lake level elevation, and 45 feet above the flood elevation assumed to occur due to the Probabl e Maximum Flood postulated to occur on Lake Anna. The terrain near the ISFSI site varies from Elevation 336 feet msl northwest of the ISFSI to Elevation 250 feet msl near the lake.

The North Anna River rises in the eastern slopes of the southwestern mountains in the Appalachian Range near Gordonsvil le, Virginia, flows into the Lake, and then continues along a southeasterly course to its confluence with the South Anna River 5 miles northeast of Ashland, Virginia, where the Pamunkey River is formed. The Pamunkey River continues on a general southeasterly course to West Point, Virginia, wher e it is joined by the Mattaponi to form the York River. The York River flows into the Chesapeake Bay approximately 15 miles north of Hampton, Virginia.

Revision 8-06/14 North Anna ISFSI SAR 2-8 The North Anna River drains a watershed of 343 square miles above the dam. The dam is located approximately 4 miles north of Bumpass, Vi r ginia and approximately 0.5 mile upstream of Virginia Route 601. The nearest United States Geologi cal Survey (USGS) stream gauging station on the North Anna River was at the br idge at Virginia Route 601. This stream gauge had been operating from October 1978 to January 1997. There have also been gauges located at Doswell and Hart Corner, Virginia, approximately 15 miles downstream from the dam. These gauges have provided coverage since 1929. The current USGS gauge at Hart Corner monitors flow over a watershed of approximately 463 square miles. Table 2-2 summarizes the records at these gauging stations and tabula tes basic stream flow data for the dam site, which have been estimated using the gauge records as a guide for years prior to 1971, and the Partlow gauge data for years after 1977.No river control structures exist on the North Anna River other than the dam described above.There is one industrial u ser of water on the North Anna River downstream of the dam, Bear Island Paper Company, and this facility is located approximately 26 miles from the North Anna Po wer Station. There are no known industrial users of water on the Pamunkey River until it reaches the York River some 60 miles downstream at West Point, where a large pulp and paper manuf acturing plant is located. There is one known potable water withdrawal on the North Anna River, the Hanover County Treatment Plant near Doswell. This plant is located approximately 24 miles downstream from the po wer station.

The North Anna ISFSI is a flood-dry site due to the elevation of the site with respect to Lake Anna and the conservative design of storm drainage facilities within the local site area. Local intense precipitation is the controlling case for storm drainage design.

2.4.2.1 Flood History Floods due to precipitation on the watershed of the North Anna River are the only flooding conditions applicable to historical consideration. Sur ges due to tropical systems, or tsunamis are not applicable to this site. The site is also not influenced by tidal effects. Gauge records have been available since the late 1920s at the USGS gauge near Doswell and in later years at Hart Corner (Reference 3). In this time the most serious flooding on the North Anna River that occurred took place in 1969 due to the remnants of Hurricane Camille (Reference 4). The second largest event on gauged record was in 1972 with the passing of th e remnants of Hurricane Agnes through the watershed. Two smaller events occurred in 1928 and 1937 (Reference 5). The largest twelve floods on gauged record are listed in Table 2-3.The average annual flood on the North Anna River near Doswell is approximately 7000 cfs.

Revision 8-06/14 North Anna ISFSI SAR 2-9 2.4.2.2 Flood Design ConsiderationsA discussion of flood elevation levels comp ared to the ISFSI site is provided in Section 2.4.1.2. A discussion of the analysis of the Probable Maximum Flood and its basis is contained in Section 2.4.3 and Appendix 2A of the North Anna Power Station UFSAR. The effects of local intense precipitation have been tak en into account in the design of the storm drainage system for the ISFSI site. Detailed discussion of this item is contained in Section 2.4.2.3.2.4.2.3 Effects of Local Intense PrecipitationThe ISFSI site is at a higher elevatio n than the surrounding area as shown on Figure 2-8. The site is drained by gradual fine grading away from the storage pads, and a combination of earthen, and concrete channels to the exterior of the site. The southern eight acres of the site are drained by a system of earthen and concrete trapezo idal channels, and the re mainder of the site is drained via concrete culverts. This is shown on Figure 2-8. The drainage system was designed using a 10-year storm rainfall in tensity. Storm drainage channels were checked and provided with additional depth to accommodate the 100-year st orm (References 6 , 7 & 8). These channels were checked to confirm that adequate hydraulic capacity existed in the storm drain system, and that the hydraulic grade line elevations were less than the top elevations of the storage pads. Since the storage pads are located at the highest part of the ISFSI, severe floodi ng or hydrodynamic loading due to floodwater is not credible based on the 100-year storm.

====2.4.3 Probable====

Maximum Floods On Streams and Rivers Based on information presented in Section 2.4.3 and Appendix 2A of the North Anna Power Station UFSAR, the probable maximum flood on Lake Anna would result in a lake level of 264.2 feet msl at the Main Dam. The water level at the Power Station site was calculated to be 267.3 feet msl, including possible wave effects. The effects in the Sedges creek area of the Waste Heat Treatment facility would be similar to that in the main lake, however, the wave effects would be less due to decreased fetch. The ISFSI is sited at an elevation approximately 45 feet above the postulated PMF lake elevation.

====2.4.4 Potential====

As stated in Section 2.4.4 of the North Anna Power Station UFSAR, there are no dams in existence on the North Anna River, other than the Lake Anna dam, either up stream or downstream. The only impoundments in the area would be small farm ponds whose failure would not produce any measurable effect on Lake Anna, the Lake Anna dam, or any safety-related systems. Thus, because the ISFSI is at a higher elev ation than the station, the ISFSI is unaffected by flood levels due to seismically induced dam failures.

====2.4.5 Probable====

Maximum Surge and Seiche FloodingSurge and seiche flooding effects are considered in coastal or tidal areas where cyclonic activity results in increased water levels. These increased levels are due to the momentum of the storm event and the reduction in volumetric flow area near the coast (References 9 & 10). The Revision 8-06/14 North Anna ISFSI SAR 2-10 North Anna Power Station is approximately fort y miles upstre am from th e confluence of the North Anna river with the South Anna near Doswe ll. The Pamunkey River becomes tidal in the region of the US 360 bridge approximately thirty-six miles downstream of this confluence. Surge effects would dissipate with distance from the coast, available storage of floodwater, elevation above sea level, etc. Therefore, surge flooding is not considered credible. Since the Power Station and the ISFSI site are not within an enclosed or semi-enclosed bay or harbor, seiche due to free oscillations is not applicable. Seic he due to forced oscillations is applicable primarily to coastal situations and as stated previously, the ISFSI site is inland.

====2.4.6 Probable====

Maximum Tsunami Flooding Tsunami flooding is not a co nsideration for the North Anna site because of its inland location (Reference 9).2.4.7 Ice Flooding As discussed in Section 2.4.1.2 , the North Anna ISFSI is approximately 60 feet above the normal level of Lake Anna. The fo rmation of ice on Lake Anna would not have an effect on the ability of the North Anna ISFSI site to drain properly.

====2.4.8 Flooding====

Protection Requirements The ISFSI is situated well above the maximum water level occurring on Lake Anna. As stated in Section 2.4.1.2 , the ISFSI site grade is 60 feet above the normal stil lwater level of Lake Anna. There are no special precauti ons that need to be taken to protect SSSCs on the storage pads.

are no liquid or gaseous releases that could result from operation of the North Anna ISFSI.2.4.10 Subsurface Hydrology 2.4.10.1 Regional Characteristics and Site Characteristics The hydrologic boundarie s of the North Anna Power Station site proper are Lake Anna on the north and east, Freshwater Creek approximately three miles to the west, and Elk Creek approximately four miles to the south. A description of groundwater conditions and onsite use are discussed in Section 2.4.13 of the North Anna Power Station UFSAR.

The hydrologic boundaries of the North Anna ISFSI site consist of a trib utary to Sedges Creek to the west and s outh of the site, Canal A to the east, and Lake Anna to the north. The closest distance to Lake Anna to the north is located near the Unit 2 intake structure which is approximately 3000 feet away. The distance to Canal A is approximately 2500 feet to the east.

The closest distance to La ke Anna in the Waste Heat Treatment Facility is 1500 feet to the southeast. A tributary to Sedges Creek, however, varies from less than 100 feet to the west of the Revision 8-06/14 North Anna ISFSI SAR 2-11 ISFSI to 1000 feet directly to the south of the ISFSI.

Figure 2-9 depicts the ISFSI and its location with respect to the lake.The elevation of rock surface varies at the ISFSI site from Elevation 272 feet msl to Elevation 245 feet msl. The groundwater generally moves along this rock surface until it exits the ground surface as springs, or into the lake. There are three permanent groundwater monitoring wells that have been installed onsite, one upgradient and two downgradient. The average groundwater elevation of the upgradient well is 296.3 feet msl. The average groundwater elevation of the southwesterly downgradient well is 289.0 feet msl. The average groundwater elevation of the southeasterly downgradient well is 280.3 feet msl. The average elevations cited are b ased on a three month period in which the readings were taken.

The southwesterly gradient is approximately 0.01 ft/ft, and the southe asterly gradient is approximately 0.02 ft/ft. Using a horizontal coefficient of permeability of 10

-6 cm/sec, an estimate of th e seepage rate is between 1.5 and 3.0 gal/day/ft near the ISFSI. Gr oundwater from below the ISFSI site will tend to migrate towards the lake via springs, which will accumulate in the tributary stream to Sedges Creek. This groundwater will eventually move into the lake at the Sedges Creek "arm" of the Waste Heat Treatment Facility.

2.4.10.2 Onsite and Offsite Water UseWater for domestic use at the pl ant site is taken from groundwat er wells. There are currently seven wells in use at the Power St ation. The closest of these to the ISFSI s ite is approximately 1500 feet away to the east near the North Anna Nuclear Information Center (NANIC).The closest offsite well to the ISFSI site is in a resi dential area ap proximately 3500 feet away to the south. As discussed in Section 2.4.10.1, the groundwater regime below the ISFSI site will tend to move water to the trib utary of Sedges Creek directly to the south of the site, and eventually into the Lake. The wells in this residential area are drilled very close to the lake and the effects of the presence of the lake (hydrostati c pressure), and distance from the site would preclude any groundwater movement fr om the ISFSI to this location.

2.4.11 References 1.Site Environmental Studies, Proposed North Anna Power Station, Louisa County, Virginia, Dames & Moore.

2.Site Environmental Studies, North Anna Power Station Proposed Units 3 & 4, Louisa County, Virginia, Dames & Moore.3.Water Resources Data for Virginia, U.S.

Geological Survey Water-Data Reports, 1961 through 1993.4.Flood of August 1969 in Virginia, U.S. Department of the Interior, Geological Survey, Water Resources Division, 1970.

Revision 8-06/14 North Anna ISFSI SAR 2-125.Floods in Virginia, Magnitude and Frequency, U.S. Department of the Interior, Geologic Survey, Water Resources Division, E. M. Miller, 1969.6.Drainage Manual, Virginia Department of Transportation, 1989.

7.Applied Hydrology, Chow, Maidment and Mays, 1988.

8.Open Channel Hydr aulics, Chow, 1959.

9.Handbook of Coastal and Ocean Engineering

, Vol. 1, Wave Phenomenon and Coastal Structures, John B. Herbich, Editor

.10.Shore Protection Manual, Vol. 1, Coastal Engineering Research Center, Department of the Army, 1984.

===2.5 GEOLOGY===

2.5.1.2 Geologic History of Storage Site and Surr ounding Region The ISFSI site is located within an area of the eastern North American craton that has undergone extensive tectonism since Precambrian time. This has resulted in a complex pattern of Revision 8-06/14 North Anna ISFSI SAR 2-13regional folding and faulting. Three of the periods of tectonism in the P aleozoic era were the result of a collisional or accretionary tectonic style, while th e last period of tectonism was generally a continental rifting, or extensional style of deformation. Th is last period of tectonism in the late Jurassic and early Triassic resulted in the formation of the numerous downfaulted Triassic basins that exist along the eastern margin of North America, from Connecticut to Georgia.

2.5.1.3 Specific Structural Features of Significance The ISFSI site lies ad jacent to the North Anna Power Station u pon a bedrock lithology mapped pre viously (Reference 1), and shown in Figure 2-10 , as hornblende gneiss. The hornblende gneiss, which is th e dominant lithology, is genera lly an interbedded sequence of hornblende gneiss, biotite granite gneiss and granite gneiss. As shown in Figure 2-10 , the dominant lithology ons ite is the interbedded hornblende gneiss/biotite gran ite gneiss/granite gneiss sequence, with the massive granite gneiss unit being subordinate.

Both units as mapped onsite are part of the Ta River Metamorphic Suite, mapped and classified by Bobyarchick, et al. (1981) (Reference 2). The Ta River occurs west of the Spotsylv ania Lineament (a northeast-southwest trending aer omagnetic lineament described belo w), and is generally composed of amphibolites, amphibole gneiss and mi nor biotite granite gnei ss and schist units.

The dominant structural featur es noted during deta iled geologic mapping at the site in 1973 (Reference 1) are shown in Figure 2-10. The site is located on the northwest flank of a northeasterly trendi ng, gently plunging (15 degrees) to the north, ant iform. During the Paleozoic era, these rocks were deformed repeatedly and resulted in the polydeformational expression seen in the rocks today. Boundaries between the different units at the site were primarily affected by flexural slip folding during that era as the antiform was formi ng. The resulting deformation along one of these boundari es formed the Zone A Chlorite Seam that was the object of the very detailed geologic investigation in 1973 because of its location relative to Units 1 through 4 of the North Anna Power Station. Details describing this geologic investigation can be found in Section 2.5.2.4 of the North Anna Power Station UFSAR.The closest fault to the site othe r than that described above is located near Mineral, Virginia, some six to seven miles west of the site. The fault has no surface expression and is known only from exposures in underground mine workings near Mineral. The known length of the fault is approximately 1000 feet, with a projected max imum length of several mile

: s. If projected along its strike of N20

The locations of recent bori ngs drilled at the ISFSI site for purposes of developing subsurface information for foundation design and for confirming bedrock geology characteristics are shown on Figure 2-11. Figure 2-12 presents a subsurface cros s-section of the bedrock and overlying soils beneath the storage pads. The bedrock encountered in the core retrieved from the borings confirms the previous bedrock mapping and interpretation made in 1973. Additionally, fractures identified in the core were consistent in both frequency and general orientation relative Revision 8-06/14 North Anna ISFSI SAR 2-14to the core as those observed and mapped in the excavations for Units 3 and 4 and elsewhere onsite in 1973. No structur al zones similar to wh at was observed in Units 3 and 4 during the 1973 geologic investigation were observed in the core retrieved from the recent ISFSI borings. Foliation observed in the core ranged from 35 to 50 degrees (interpreted to be dipping to the northwest based on pre vious mapping onsite).Details regarding the recovery and rock quali ty designation (RQD) valu es are contained in Table 2-4. The boring logs and logs of the rock cori ng for the bedrock investigation, are provided in Appendix 2A.A brief description of structural features of significance is provided below. Additional details regarding the site can be found in Section 2.5.3.1 of the North Anna Power Station UFSAR.1.Hylas ZoneIn a section of the Piedmont and Triassic subprovince approximately 25 km west of Richmond, and to the south-southeas t of the site, lies the Hylas zone which trends roughly northeast (Figure 2-13). This is a group of mylonitic rock s produced by late Paleozoic ductile shearing of pre-existing biotite gneiss, granite gneiss, and amphibolite. The rocks west of the Hylas zone (between Columbia and the Hylas zone), referred to as the Goochland complex, are metamorphosed sedimentary and igneous rocks consisting of biotite gneiss and schist, granite gneiss, amphibolite, and granite.The Petersburg granite, a coarse-grained unit, bounds the eastern margin of the Hylas zone at Hylas and northeastward to the Taylorsville Basin. It is a two-feldspar muscovite-biotite granite with at least one poorly to moderately developed tectonic foliation. Emplacement of the Petersburg granite occurred prior to the formation of the Hylas zone since field mapping indicates mylonitic rocks are gradational into relatively unaltered granite (Reference 3).Rocks in the Goochland complex west of the Hylas zone underwent at least tw o deformations (D l , D 2) prior to ductile shearing in the Hylas zone (D 3). D 3 was responsible for a mylonitic foliation (S c) and a later widely-spaced shear cleavage (S s) to be formed in rocks in the Hylas zone. At about 220 Ma, brittle deformation was superimposed on the Hylas zone in the form of high-angle faulting and locally intense fracturing (D

: 4) which is probably equivalent to the Palisades disturbance of New England. D 4 was associated throughout the Piedmont with synchronous downwarping and dominantly continental sedimentation to form a series of parallel Triassic basins represented locally by the Richmond Basin. Northwest-oriented high-angle faults that apparently displace Triassic sedimentary rocks are interpreted to have occurred prior to the Late Cretaceous (Reference 3).The Goochland complex underwent re gional prograde metamorphism to amphibolite facies (M 1) and included D 1 and D 2; structural elements that compose these deformational events consist mainly of oriented metamorphic minerals. Well-equilibrated microstructures seen in Revision 8-06/14 North Anna ISFSI SAR 2-15 the gneiss suggest that the M 1 peak persisted past D

: 2. M 1 is interpreted to have occurred approximately 340 Ma. During the late Paleozoic time, D 3 was accompanied by retrograde metamorphism (M

: 2) to greenschist facies in the Hylas z one. The Hylas zone may continue to the north in the Brandywine area of the Coastal Plain as indicated by Cenozoic reverse faulting 90 km along the strike of the Hylas zone (Reference 4). Current stress release beneath the Coastal Plain may be influenced by the Hylas zone and analogous fault systems throughout the Piedmont (Reference 2).2.Stafford Fault SystemVarious field investigations of the upper Meso zoic and Cenozoic dep o sits of the Inner Coastal Plain of Virginia between Washington, D.C. and Richmond, Virginia have revealed evidence of faulting of Coastal Plain beds. In 1976 Newe ll and others (Reference 5) recognized and described the Stafford fault syst em which is a series of end echelon, northeast striking, northwest dipping, high-angle reverse faults that displace both the Apostolic rocks of the Piedmont and the overlying Coastal Plain sediments. The Stafford fault extends for more than 33 miles along the Virginia Fall Line and th e northeast-trendin g reach of the Potomac River. Mixon and Newell (1977) (Reference 6) believe that the position of the Stafford fault system supports the hypothesis that the Fall Line and major river deflections along it have been tectonically influenced (Reference 7).Fault movement along the Staffo rd system be gan as compressi onal deformation at least as early as the Early Cret aceous. A detailed trench study of the Du mfries fault zone west of Stafford, Virginia is of special significance: Ordovician slate, phyllite, and schist have been thrust at a high angle over the lower Cretaceous Potomac Formation. Likewise, major deformation occurred in the middle Tertiary and pre-Choptank time. There is as much as 1-1/2 feet of reverse fault offset at the base of th e upland gravel in an artificial cut near the US 1 highway bypass in south Fredericksburg, Virg inia which indicates that at least some Pliocene deformation occurred along the Stafford system. "Approximately 1.0 foot of fault offset of the base of high-level Rappahannock River terrace deposits by the Fall Hill fault, which is a major strand of the Stafford system, indicates middle to late Pliocene or, possible, younger faulting." (Reference 7)Mixon and Newell (1977) (Reference 6) noted the alignment of zones of compressional faulting in the Maryland and Virginia Coastal Plain in linear zon es of early Mesozoic extensional faulting in the Pi edmont and in the crystalline basement beneat h the Coastal Plain. The early Mesozoic extensional faults and the Coastal Plain compressional fault zones are, in turn, aligned with Paleozoic thrusts and shear zones in the underlying basement rock. In Virginia, for example, the Stafford fault system is aligned with the border faults of the early Mesozoic Farmville basin trend and with the Spotsylvania magnetic lineament (Reference 5).

Revision 8-06/14 North Anna ISFSI SAR 2-16 During 1976, Dames & Moore (Reference 4) investigated the age a nd geologic origin of the Stafford fault system, which approaches the site at its closed point, approximately 22 km northeast in the vicinity of Fredericksburg. The detailed dr illing, trenching and mapping program demonstrated that the youngest identifiable fault movement on any one of the four structures making up the Stafford fault system was pre-mid-Miocene in age, or more than 10 million years ago. Accordingly, the Stafford fa ult system is not capab le in the meaning or intent of Appendix A to 10 CFR 100.3.Spotsylvania LineamentThe Spotsylvania lineament is a northeast-t rending aeromagnetic anom aly that separates the Ta River and Po River Metamorphic Suites. To the west of the lineament, and where the North Anna Power Station is located, the Ta Rive r rocks are characterized by linear , northeast trending medium to high intensity anomalies; however, to the east of the lineament, the Po River terrane is characterized by relatively lower intensity, north-trending anomalies. Researchers believe that the Spotsylvania lineament represents a fault or system of faults to explain its regional linearity. Microstructures and field data indicate that the Spotsylvania lineament, if it represents a fault, formed during or before regional metamorphism (Reference 2).Inasmuch as the Spotsylvania lineament is directly on strike with a projected extension of the Stafford fault system to the s outhwest, Dames & Moore (1977) (Reference 8) investigated the minimum age of the Spotsy lvania lineament (then known as Neuschel's lineament) by categorizing and mapping the extent and continuity of a Pre- or Early Cretaceous erosion surface across the extent of the lineament. Dames & Moore's findings were that the lines of evidence discerned indicated a minimum age of movement of 100 million years (Early Cretaceous) if the lineament were indeed a fault zone, and that it is not structurally related to the Stafford fault system.4.Mountain Run Fault ZoneThe Mountain Run fault zone (MRFZ) is a re gional feature approximately 75 km in length. It is best defined as a physiogr aphic feature, in the form of a northeast-trending linear fault-scarp, in the Unionville, Virginia quadra ngle. The northern end of the MRFZ forms part of the southeast boundary of th e early Mesozoic Culpeper ba sin. The scarp is "held up" by phyllonite which extends over a width of at least 2-1/2 km to the southeast of the scarp. On the northwest side of the scarp lies an alluvium-filled valley. The northwest side of this valley is a narrow zone of faulted and sheared rock s that form the northwest boundary of the MRFZ.

Mapping indicates that the MRFZ extends from about the Mesozoic basin near the Rappahannock River southwestward to near Charlottesville, Virginia (Reference 9).On its southeast side, the MRFZ separates a thrust-faulted early Paleozoic (pre-440 Ma) melange terrane from a phyllite, slate, and limestone unit that uncomformably overlies the Precambrian Catoctin Greenst one; together these are cons idered as part of ancestral (pre-400 Ma) North America. Therefore, the MR FZ is thought to be a suture which Revision 8-06/14 North Anna ISFSI SAR 2-17"juxtaposed a Cambrian island arc (Central Virgin ia v olcanic-plutonic belt) and its associated fault-imbricated back-arc basin (melange terrane) onto or against ances tral North America in pre-440 Ma." In early Mesozoic time, part of the MRFZ was reactiv ated to partly delineate the southeast boundary of the Triassic-Jurassic Culpeper basin. According to Pavlides (1986)

(Reference 9), there may have been additional loca l reactivation within the MRFZ during the late Cenozoic time indicated by th e recent (ca. 1986) discovery of a thrust fault within the MRFZ that offsets gravels of probably post-Pliocene age (Reference 9).5.Giles County ZoneA series of five extensional fa ults were recently uncovered in new excavation for landfill material adjacent to the New River in Giles County, Virginia, some 220 miles west-southwest of the site (Figure 2-13). The faults strike about N50°E and dip either no rthwesterly or southeasterly. The structures displace alluvial terrace deposits of suspected Tertiary or Quaternary age. Seismic monito ring in this part of the Valley and Ridge Province over the past 20 years indicate that earthquake foci ar e located at depths greater than 5 km (Reference 10).2.5.1.3.1 Regional GeologyThe predominant lithologies in the region surro unding the site include rocks of the Central Virginia Volcanic-Plutonic Belt, the Ta River and Po River Metamorphic Suites and interlayered mafic and felsic metavolcanic rocks. The Falmouth Intrusive Suite and the Quantico Formation are rocks of the Central Virginia Volcanic-Plutonic Belt. The Falmouth Intrusive Suite is composed of fine-grained to pe gmatitic granite, quartz monzonite, granodiorit e, and tonalite and also consists of dike, sills and small plutons. This unit has been dated at about 300 to 325 Ma and locally intrudes the Ta River Metamorphic Suite and the Quantico Formation. The Quantico Formation is predominantly a slate and porphyroblas tic schist. This unit contains gray to black, graphitic, pyritic p hyllite and slate (in th e northern Piedmont) wh ose metamorphic grade increases to the southwest to produce porphyroblastic staurolite-, kyanite-, and garnet-biotite-muscovite schists. This unit reaches a thickn ess of up to 3000 feet. The Quantico Formation is Ordovician in age and unconformably overlies older units in the northeastern Piedmont. It is correlated with the Arvonia Formation to the southwest (Reference 11).The Ta River Metamorphic Su ite is a layered sequence wh ich consists mainly of greenish-gray to black, medium to coarse-grained, poorly to well lineated, massive to well-layered amphibolite and amphibole-bearing gneiss and schist. Likewise, this suite contains interlayered ferruginous quartzite, and minor biotite gneiss and schist, felsic volcanic rocks, gabbro and granite. The amphibo litic rocks commonly contain quartz-epidote lenses and veins. The grade of regional metamor phism increases from northeast to southwest along strike as does the proportion of biotite gneiss and schist. Pavlides (Reference 12) correlated the Ta River with the James Run and Chopawamsic Formations, an d considered the Ta River to be a more oceanward facies of a Chopawamsic island arc sequence, based on geologic and geochemical factors. The Ta River is Cambrian in age. The Quantico Formation generally overlies the Revision 8-06/14 North Anna ISFSI SAR 2-18boundary between the Ta River and the Chopaw amsic, obscuring the contact relationships (Reference 11).The Po River Metamorphic Suite, which lies to the east of the Ta Rive r Metamorphic Suite, is characterized primar ily by biotite gneiss with lesser amounts of hornbl ende gneiss and schist. Furthermore, pegmatoid and granitoid dikes are abundant. "The age of the Po River is uncertain, but may be considered Proterozoic Z and (or) early Paleozoic based on its stratigraphic position underlying the Ta River Metamorphic Suite and the Holly Corner Gnei ss, both correlated with the Lower Cambrian Chopawamsic Formation." (Reference 12)Ferruginous quartzites, which are distinctive local marker units , locally delineate map-scale structures in some places. "Thi s lithology is recognizable in rocks of variable degree of deformation and metamorphic grade; it has been mapped within the Ta River Metamorphic Suite and within correlative unnamed interlayered mafic and felsic metavolcanic rocks to the southwest." (Reference 11)2.5.1.3.2 Regional TectonicsSince the time of the initial geologic investigation at the North Anna Power Station, two major tectonic models ha ve emerged to explain the evolut ion of the central and southern Appalachians. The initial model was presented in 1972 by Hatcher, which proposed that the eastern Piedmont volcanics (C harlotte, Caroline Slate, Raleigh, and eastern slate belts) represented a late Precambrian to Early Ordovician island arc on the eastern edge of Laurentia. An Andean-type orogeny during the Middle Ordovician-Silurian was presumed to have formed by westward subduction of oceanic crust. Collision with Africa, during Mid-Late Devonian to Permian, resulted from continued westward subduction and produced the Acadian and Alleghanian orogenies. Following Hatcher's model in 1972, Od em and Fullagar and Rankin suggested models in which the Brevard zone along the Eastern Blue Ridge was a suture (Reference 13).In 1978, Hatcher revised his ea rlier model increasing the numb er of sutures from one to three. Between 800 and 700 Ma, the basements of the Inner Pi edmont and Charlo tte/slate belts were thought to be continen tal fragments rifted from Laurentia. From about 700 to 450 Ma, subduction towards the west draped the outer frag ment with Charlotte/slate belt volcanics. Concurrently, the oceanic basins between the Laurentian continent/Inner Piedmont and Charlotte belt/slate belt fragments were closing, culminating in the Taconic Orogengy during the Middle/Late Ordovician. Oceanic crust contin ued to subduct to the west beneath the Charlotte/slate belt, which eventually closed th e Iapetan Ocean. Continental collision with Africa took place in the Acadian/Alleghanian orogenies during the Late Paleozoic (Reference 13).In 1980, Hatcher and Odom modified the 1978 m odel to include: T aconic collision between the North American craton and the Piedmont fragment; Ac adian collision between the Piedmont-North American block and Avalonia; and the Alleghanian collision between Africa and Avalonia (Reference 13).

Revision 8-06/14 North Anna ISFSI SAR 2-19Coney and others (1980) estab lished the suspect terrane conc ept which w as formalized in the western North American Cordillera. This concept initiated the beginning of a new tangent in the development of Appalachian tectonic models. In 1982, Williams and Hatcher published a paper on the accretionary history of the Appalachians, essentially discarding the model proposed by Hatcher in 1978 for the sout hern and central Appalachians, but added several new terranes thought to possibly be bounded by suture zones. Since that time, others have proposed that the southern and central Appalachians are divide d into numbers of mic ro-terranes each bounded by possible sutures (Reference 13).In 1982, Glover and othe rs presented another model, dif f erent than the one proposed by Williams and Hatcher, to explain the tectonic configuration of the Appalachians. They concluded that the only suture in the Piedm ont and the Blue Ridge of the central and southern Appalachians is the Taconic suture, based on the ages of ductile deformation and metamorphism in the central and southern Appalachians. The Taconic suture is found along the wester n boundary of the Kings Mountain belt in North Carolina and extends into Virginia along the western boundary of the Charlotte belt and Chopawamsic volcanics. Likewise, Glover and others believe that other sutures, of Acadian and/or Alle ghanian ages, must lie under the Atlantic Coastal Plain or offshore in basement rocks (Reference 13).In 1987, Hatcher further revi sed the Hatcher and Odom (1 980) model to include the Penobscottian orogeny (early Cambrian to Early Ordovician) as an early stage in the collision of the "Piedmont arc" with th e North American craton (Reference 13). Additional details regarding the regional tectonic character istics of the area around North Anna Power Stati on can be found in Section 2.5.2.4 of the North Anna Power Station UFSAR.

2.5.1.4 Large Scale Geologic Map The locations of the struct ural feature discussed in Section 2.5.1.3 are shown in Figure 2-13.2.5.1.5 Plot Plan and Site Investigations Soil borings and laboratory tests were pe rforme d as part of the development of the North Anna Power Station license a pplication. The boring logs and site maps showing the boring locations are contained in Appendix 2C of the North Anna Power Station UFSAR. Additional borings and laboratory tests were performed in the area of the Service Water Reservoir. Results of these borings and test s are contained in Appendix 3E of the North Anna Power Station UFSAR. An investigation consisting of so il test borings, rock coring, and laboratory tests w as performed at the ISFSI site to ident ify and document site geotechnical conditions and to develop soil parameters required for evaluation of design requirements. Two soil test borings were performed in 2008 to support development of the alternate transport route. Re sults of the borings and rock coring are contained in Appendix 2A and laboratory tests are contained in Appendix 2B of this document.

Revision 8-06/14 North Anna ISFSI SAR 2-20The geologic portion of the field investigati on for the siting of the ISFSI at the North Anna Po wer Station consisted of:1.The logging and preparation of bedrock bori ng logs for eight borings, using standard techniques; and2.Examination of weathered bedrock exposur es in a borro w pit west of the North Anna Power Station switchyard and close to a tributary arm of Lake Anna.The purpose of the field geologic investigatio n was to ascertain the physical nature and characteristics of the bedrock from the cores retrieved from the borings, as well as the limited exposure afforded in the borrow pits, in order to compare them to previous onsite geologic investigations in 1973 and 1974. The field geologic investigation was performed by a geologist from Dames & Moore.

2.5.1.5.1 Field InvestigationAt the direction of Vi rginia Power, eight borings (F-4 through F-11) were drilled in June through July of 1994 at the proposed ISFSI storage pad locations as shown on Figure 2-11. The borings were located in plan an d elevations by Stone & Webster surveyors. Boring F-2, drilled in April 1994 for a preliminary invest igation and located at the North end of the center storage pad is also included herein. In addition, seven shallow borings desi gnated P-l through P-7 were drilled along the original (main) transport route. The so il test borings were drilled by Froehling &

Robertson, Inc. (F&R) using a Cent ral Mining Equipment (CME), Model 55 truck mounted drill rig by mechanically advancing continuous flight hollow stem augers into the soil. At regular intervals a standard 1.4-inch i.d., 2.0-inch o.d., 20-inch long split spoon sampler was driven into the soil with a 140 lb hammer falling 30 inches in accordance with Am erican Society for Testing and Materials (ASTM)

D1586 Standard Penetration T est (SPT) procedures (Reference 14). SPT results provide an indication of compaction, strength and support cap acity of the soil. SPT tests were performed continu ously to depths of 4.5 feet, from 6.0 to 7.5 feet, 9.0 to 10.5 feet, and at five-foot intervals thereafter to spoon or auger refusal (rock). Di sturbed split-spoon samples were collected with each SPT and visually classified by a geotechnical engineer from Virginia Power. The boring logs showing elevati on and depth of samples, penetration resistances (blow count), soil stratum description and Unified Classification, and groundw ater information are contained in Appendix 2A.Where borings could no l onger be advanced with standard soil boring equipment, rock was cored. A water-cooled double-tube NX-size core barre l with diamond studded bit was used to secure the rock cores. The core recovery from each five foot long run was examined and classified by a geologist from Dames & Moore. The percent recovery, which is the ratio of the recovered length to the total length of run, was calculated for each run. The RQD was also calculated for each five-foot run. RQD is the ratio of the cumulative length of pieces of core greater than 4 inches long compared to the total length of run. RQD is an index to the soundness and quality of the rock. Core recoveries and RQD values for all core runs are contained on the boring logs and are provided in tabular form in Table 2-4.

Revision 8-06/14 North Anna ISFSI SAR 2-21 Split spoon samples are su itable for visual e xamination and classification (index) tests but are not sufficiently intact for quantitative labora tory testing. Six relatively undisturbed samples were obtained by forcing sections of 3-inch o.d., 16 gauge, steel tubing into the soil at the desired sampling levels. This sampling procedure is described by ASTM Specification D-1587 (Reference 15). Each tube, together with the encase d soil, was carefully removed from the ground, made airtight, a nd transported to the laboratory. Loca tions and depths of undisturbed samples are shown on the boring logs. Five add itional undisturbed sampl es were obtained by pushing sampling tubes into the soil using a backhoe bucket.Five monitoring wells were in stalled at locations across the site. These wells consist of slotted well screens attached to 2-inch diameter PVC riser pipe. Filter sand w as placed around the screen and a bentonite seal was placed above the well screen and sand. The annular space around the pipe and soil above the seal was filled to the surface with cement grout. Logs of the monitoring wells are also contained in Appendix 2A.The locations o f the two soil test bori ngs conducted by MA CTEC Engineering and Consulting, Inc. in April 2008 along the alternate transp ort route are shown in Figure 2-18. These borings, designated B-713 and B-714, were each drilled to 20 feet depth. The borings were advanced by a CME 550x drill rig using hollow-stem augers with 4.25-inch inside diameter and a nominal 8-inch outside diameter. The soil was sampled using an SPT sampler at 2.5-feet intervals to 15 feet depth, with a final sampl e being taken between 18.5 to 20 feet depth. The SPT was performed using an automatic hammer , and was conducted in accordance with ASTM D 1586. The recovered soil samples were visually described and classified by the MACTEC geotechnical technician. Pocket penetrometer (PP) tests were performed in the field on the lower end of the samples. No laboratory testing was performed on samples from these two borings, and no intact samples were collected. All of the borings were backfilled wi th a cement/bentonite grout upon completion.

2.5.1.5.2 Laboratory TestingThe following tests were perf ormed on selected split spoon , b ulk, and undisturbed samples. Results of the test are contained in Appendix 2B:Name of Test ASTM Standard Reference No.Test PerformedParticle (Gradation) Size Analysis D422 and D1140 16 and 17 19Atterberg Limits D4318 18 3Natural Moisture Content D2216 19 19 Moisture Density Determination D1557 20 2 California Bearing Ratio (CBR)

D1883 21 6Consolidation Test D2435 22 3Triaxial Shear Test D2850 23 2Unconfined Compression Test D2166 24 5 Constant Head Permeability D2434 25 1 Revision 8-06/14 North Anna ISFSI SAR 2-22 2.5.1.5.3 Borrow Pit ExposureA borrow pit, located approximately 1000 feet west of the North Anna Power Station switch yard (Figure 2-10), was used to provide fill for a numbe r of onsite projects over the last five to ten years. Its location in re lation to a previously-mapped fold axis would have provided additional confirmation of the presence of the fold axis and the interpreted bedrock geology from saprolite exposures during th e 1973 onsite geologic mapping.

During the onsite logging of the core retrieved from the ISFSI site borings, the borrow pit was visited by the geologist from Dames & Moore to map the exposed bedrock. The borrow pit, unfortunately, had been in-filled and graded to reclaim and replant the e xposed saprolite slopes. Enough exposed saprolite bedrock could be observed, however, to confirm that the interpreted bedrock at that location was indeed granite gneiss, and that the fold axis was within the exposure limits. It was observed that the fo ld axis, although not directly meas urable because of the lack of complete exposure of the saprolite bedrock, would have been ali gned in a northerly direction and plunging gently. This is consis tent with the orientat ion of F2 folds in the Lake Anna East Quadrangle west of the Spotsylvania Lineament (Reference 1).2.5.1.6 Geologic Profiles Based on the information gathered from the eight borings and associated sampling and testing obtained in June and July 1994, the following stratigra phic sequence is inferred to underlay the site.Surface elevations, depth of r esidual soil and quality of rock v aried moderately across the site. The materials encountered consist of residual soil derived from the in-place weathering of the parent metamorphic rock. The typical soil profile consists of clay minerals near the ground surface which were converted from the feldspars, micas, and ferro magnesi an minerals contained in the parent rock. At depth, these minerals become less weathered and onl y partially altered, retaining their inter-particle bonding. Below the firm surficial clays and clayey silts (ML and MH), the soil grades from a fine sandy silt to a silty fine sand (SM to SP) with varying amounts of mica. The soils possess highly plastic fines in varying amounts, th erefore, the characteristics of the fine grained soils and predominantly granular soils with some fines and mica are similar. The transition between the surficial fine grained soils and the more granular soil s encountered with depth is gradual.

Note: 1 ASTM D2850 is the standard for the Unc onsolidated Undrained Triaxial Shear Tests. One Consolidated Undrained Shear Test with pore pressure was also performed. Currently there is no ASTM standard for the Consolidated Undrained Shear Test.Name of Test ASTM Standard Reference No.Test Performed Revision 8-06/14 North Anna ISFSI SAR 2-23 The penetration resistanc es (SPT) are higher in the surf icial clays and clayey silts, drop off in the highly micaceous silty soil s, and pick back up in the sandy soil and decomposed rock above the less weathered parent rock. Th e deeper residual soils retain the original fabric or bonding of the parent rock and are termed saprolites. The sapr olite retains the foliatio n of the parent rock along with interparticle bond. There is no well defined boundary between soil an d rock, only a transition.The generalized soil profile as encountered by the borings across th e ISFSI site is as follows. The surficial fine grained clayey silts (ML and MH) extend to depths of 7 to 29 feet in all but two borings. In borings F-5 and F-8, the clayey silt extends all the way to rock. These soils are stiff to hard in consistency and possess good to excellent strength and support capacity.

The more granular sandy micaceous silt and micaceous silty fine sand (SM and SP) are encountered below the cohesive material and normally extend to rock. However, in two of the borings, F-9 and F-10, silty fine sand was pres ent from the ground surf ace to the top of rock. This material was medium dense to very dense in consistency with only a few SPT results falling below 10 blows per foot.As shown on the boring logs (contained in Appendix 2A), the lithologies penetrated by the borings are entirely consistent with those mapped and shown on Figure 2-10. The ISFSI is located entirely within a unit ma pped as interbedded hornblende gneiss, biotite granite gneiss and granite gneiss, with the predominant lithology being hornblende gneiss.Rock as defined by auger or s poon refusal and the initiation of rock coring was encountered at elevations vary ing from 245 to 272 feet. All of the cores retr ieved, except fo r portions of Borings F-10 and F-4, were extremely weathered. Primary structures in the rock, however, are still recognizable. Table 2-4 provides a summary of the percen t recovery and percent RQD values for all eight borings. Recovery varies from 0 to 95%, and RQD values vary from 0 to 35.8%.Fractures are clearly observable, even in th e most weathered of the cores. Typically, fractures vary from near horizontal to about 70 degrees from the vertical. Almost all fractures observed have iron and manganese staining on the fracture surfaces, indicative of groundwater flow. Slickensides were not observed on any of the fractures. This is not surprising, as the borings penetrate a rock mass away fro m those boundaries (such as Zone A) that underwent primarily fle xural slip deformation during tectonism in the Paleozoic.Foliation in the hornblende gneiss is we ll developed, with elongation of individual hornblende crystals. Foliation dip observed was between 35 and 50 degrees, which is consistent with the closest field observation point (Figure 2-10).Groundwater was encountered at depths of 19 to 27 feet below existing grade (Elevation 289 to 296 feet) across the site seve ral days after completion of indi vidual borings. The groundwater level is at least 20 feet below the proposed final elevation of Elevation 311 feet.

Revision 8-06/14 North Anna ISFSI SAR 2-24 Figure 2-12 presents a geologic profile across the site showing the soil and rock stratigraphy as discussed above.The soil profile interpreted from Borings B-713 and B-714 drilled fo r the alternate haul route in 2008 is shown in Figure 2-19. Very stiff sandy clay fill w as encountered in the top 5 feet of B-713, reducing to about 3 feet at B-714. Below the fill, the na tive saprolitic soils extend to the bottom of the borings at 20 feet depth. The saprolite consists of medium dense sandy silt (ML) underlain by medium dense silty sand (SM). About 5 ft of clayey topsoil w as encountered beneath the fill in B-713.

2.5.1.8 Local Geologic Features Affecting Site Location The location of recent borings drilled at the ISFSI site for the purposes of developing subsurface information for foundation design and for confirming bedrock geology characteristics are shown in Figure 2-11. Figure 2-12 presents a subsurface cross-section of the bedrock beneath the ISFSI storage pads. The bedroc k encountered in the core retrieved from the borings confirms the previous bedrock mapping and interpretation made in 1973. Additionally, fractures identified in the core were consistent in both frequency and general orientation relative to the cores observed and mapped in the excavations for Units 3 and 4 and elsewhere onsite in 1973. No structural zones similar to those observed during the 1973 geologic investigation were observed in the core retrieved from the recent ISFSI borings. Foliation observed in the co re ranged in depth from 35 to 50 degrees (interpreted to be dipping to the northwest based on pre vious mapping onsite).Details regarding the recovery and RQD va lues, and the boring l ogs for the bedrock investigation, are found in Appendix 2A.2.5.1.9 Site Groundwater ConditionsThe depth to the water table was measured in each of the borings taken in June and July 1994. The depth to the ground water was 19 to 27 feet (Elevation 289 to 296 feet). Water levels in groundwater monitoring wells three months after installation varied from Elevation 280 to 296 feet which is consiste nt with water levels obtained initially. No water was encountered in the two borings drilled in the alternate transport route (maximum depth of drilling was 20 feet).Site groundwater conditio ns are discussed in Section 2.4.2. Additional groundwater information is provided in Section 2.4 of the North Anna Power Station UFSAR.

Physical property tests cond ucted on the saprolitic soils and fresh rock included:Dry density tests on selected samplesMoisture Content TestsTriaxial Compression on undisturbed samples Particle Size Anal ysis (Gradation)Consolidation Tests on undisturbed samplesCyclic Triaxial Tests Shock Scope TestsAdditional onsite investiga tions that provide information on seismic wave propagation properties of the subsurface saprolite and rock included:Birdwell 3D Seismic LogsA Refraction Seismic Survey of the site area CA Cross Hole Shear Wave Survey of the rock supporting the reactor containments Soil and rock properties defined by the borings and laboratory test resu lts at the ISFSI site are contained in Appendices 2A and 2B. The properties developed from the ISFSI site investigation compare closely to the prope rties pre viously documented in the North Anna Power Station UFSAR and other references provided below.Shear strength tests consisting of Unconfined Compression Test and Unconsolidated Undrained Triaxial Shear tests performed on the partially saturated surficial clayey silts (ML and MH) indicated these soils possess a cohesion (c) of 1500 psf and an angle of internal friction () of 15 degrees for the total stress condition. This compares closely with an average c of 1800 psf and of 14.5 degrees obtained on extensive testing at the main dam site (Reference 26).Consolidated Undrained Triaxial Shear t est on the more granular silty sand (SM) encountered at a greater dept h and near below the water table yield a cohesion of 700 psf and a Revision 8-06/14 North Anna ISFSI SAR 2-26 of 27 degrees for the effective stress condition.

The deeper sample (F-7A, 16 to 18 feet) which classifies as a SM, is predominantly granular. Consolidation tests performed on material shows significant curv ature at slightly less than the expected overburden pressure. Disturbance may also be present in this sample.For these reasons results of th ese Consolidation T ests were not used in estimating settlement on this project. Results of previ ous testing on similar material from the same geologic formation was used. An average Recompression Ratio of 0.024 was used to estimate consolidation settlement. An average initial target modulus (E s) of 500 ksf was used in elastic settlement estimates (Reference 27).The average unit weight and na tural moisture content as de termined from the laboratory tests contained in Appendix 2B are 100 pcf and 36% respectively. The vertical permeability, as obtained from a constant he ad permeability test, was 4 x 10-7 cm/sec, which compares closely with previously developed permeabilities.

Results of CBR tests performed for this project were compared to corresponding values for Modulus of Subgrade Reactor (k s) provided by a chart giving th e interrelationship of soil classifications and bearing values (Reference 28). The average unsoaked CBR of the near surface soils was 39 and soaked 7.5. The corresponding k s from the chart was 375 pci and 175 pci which is higher than the conservative k s of 115 pci (100 tcf) for saprolite as described in Section 3.8 of the North Anna Power Station UFSAR.No new testing was performed on the rock encountered at the I SFSI site. Due to the depth of the rock and the very small increase in loadin g which the storage pad and SSSC would impose on the rock, the physical properties of the rock are not a factor. Rock was encountered at sufficient depth as not to be an influence in bearing capacity or settlemen

: t. The rock is competent and possesses no solution cavities, sink holes, voids or caverns.No new dynamic testing was perfo rmed during the investigat ion for the ISFSI since the results of recent borings and laboratory tests were similar to those previously obtained and documented at the station and ma in dam site. Dynamic soil and ro ck properties for the site are contained in Section 2.5 of the North Anna Power Station UFSAR. A shear modulus (G) of 19,800 psi and Poisson's Ratio (µ) of 0.3 were used in design of the storage pads.

Revision 8-06/14 North Anna ISFSI SAR 2-27 2.5.1.12 Analysis Techniques and Calculated ResultsThe factor of safety against a bearing capacit y failure is defined as the ratio of the net ultimate soil bearing capacity to the net applied foundation bearing pressures. The static factor of safety considered the total dead and live loads acting on the structure. A minimum safety factor of 3.0 was established as the design c riterion. The ultimate bearing capacity was calculated using conventional bearing capacity equations for shallow strip fo otings and the appropriate bearing capacity factors for the soil parameters present (Reference 29). Bearing capaci ty for a wide footing is normally not c ritical unless the footing is subject to very heavy load and a high water table and/or very soft or loose soil conditions exist. The factor of safety against a bearing capacity failure calculated for the storage pad bearing on the stiff residual soil was significantly in excess of the required factor of 3.Settlement was estimated by calculating the im mediate elastic settlement and long-term consolidation settlement of the underlying residual soil. The elas tic and consolid ation settle ment occur at different times but are additive. However, settlement calculations utilizing the classical consolidation theories which were developed for saturated sedimentary soils are generally not appropriate for the partially saturat ed residual soils. Consolidation theory considers the soils to be cohesive, homogeneous and isotro pic. The residual soils encountered below the storage pads are only partially saturated, are highly variable and possess an interparticle bond related to the weathering of the parent rock, not the clay ion bond. Previous estim ates of settlem ent of residual soils using consolidation theory have not agreed closely with th e actual documented settlement which occurred at various structures onsite.Therefore, settlement calcul ations were also performed using empirical equations developed by Schmertmann and ot hers and utilizing r esults of correlations between STP and in-situ pressuremeter tests in residual soils (Reference 30). Based on results obtained from the two different methods, it is estimated that a total set tlement of less than 1-1/2 inches will occur under full load. This estimate assumes that only 5 feet of overburden will be removed. Six and a half to ten feet (for pad

: 1) of overburden will be re moved prior to construction of the storage pads, which would reduce the amount of settlement that would occur. This estim ate assumes that the total load will be placed on the soil in one increment, which is a very conservative assumption. The time rate of loading will decrease the actual effect of any settlement that does occur, since it will take over nine years after the initial SSSC is placed for th e storage pads to be fu lly loaded. The settlement will occur in small increments as the SSSCs are placed on the storage pads.

Revision 8-06/14 North Anna ISFSI SAR 2-28 2.5.2.1 Engineering Proper ties of Materials The static and dynamic engineering prope rties of the site are described in Section 2.5.1.11.2.5.2.2 Seismic History A complete description of the seis mic history of the si te areas, as well as a summary of all significant earthquakes to the establishment of the design basis earthquake for North Anna Power Station Units 1 and 2, are presented in Appendix 2B of the North Anna Power Station UFSAR. Table 2-5 and Figure 2-17 in this report provide an updated chronological listing (through January 1994) and a regional epicenter map, respectively, for an area of 200-mile radius around the site.

The eastern United States is ge nerally divided into four basic geologic-tectonic provinces: the Valley and Ridge, the Blue-Ridge, the Piedmo nt and the Coastal Plain. All four of these provinces are characterized by a general northeast-southwest trend. The Valley and Ridge is dominated by a structural style of large an ticline-syncline struct ures which are further complicated by faulting, igneous intrusions and the development of terrestrial sedimentary basins (Reference 1).The Piedmont Province is a large northeaste rly-trending elongated group of crystalline rocks extending for approximately 800 miles (1288 km) from Alabama to New Jersey. This pro vince is primarily characteri zed by metamorphosed sedimentary and volcanic rocks deformed into anticlinoria and synclinoria whose major axes parallel the dominant northeasterly trend of the province (Reference 1). The North Anna site is located in the north-central portion of Virginia within the Piedmont Province.The historical record of earthquakes in the A ppalachian region of the United States reveals significant differences in the seismic characteristics between the individual provinces. Generally, the activity occurs parallel to the regional structure and primarily in the Valley and Ridge and Blue Ridge Provinces northwest of the Piedmont Province (References 31 , 32 & 33). Earthquakes are found to occur with less frequency in the Piedmont Province than in the adjacent provinces.

Furthermore, none of the historical earthquakes in the Piedmont province in particular, or in the Appalachian region in general, have been reported to have caused surface displacement. There are three principal geograph ic zones in the Piedmont and Coastal Plain Provinces where there is a tendency for epicenter clustering. One recognizable geographic cluster of activity is in the South Carolina-Georgia region (Piedmont-Coastal Plan), and another is in central Virginia (Piedmont Province). The third apparent cluster of activity is along the Fall Zone (Coastal Plain and Piedmont boundary) in the Delaware-New Jersey region.The clustering of activity in Central Virginia is referred to as the Central Virginia Seismic Zone (Reference 31) and includes the North Anna site on its norther n boundary. The principal activity in this zone is some 30 miles (48 km) south of North Anna, following an east-west trend.

intensity V to VI reported within 100 miles (161 km) of the site since the end of the 18th century (Reference 34). The Central Revision 8-06/14 North Anna ISFSI SAR 2-29Virginia Seismic Zone has historically exhibited a low level of activity (2 to 10 shocks per decade), with most shocks ha ving M.M. intensity levels of III to V.(31) Based on historical seismicity, the largest intensity shock that has occurred in the immedi ate site area (within 30 km) is approximately M.M. V (Figure 2-17).The most significant earthquake in the region of the station af fectin g its design occurred near the Richmond Basin in 1774 (Intensity VI-VII), and near the Arvonia Syncline in 1875 (Intensity VII). These shocks and related zones of earthquake activity are both located within 50 miles of the site, and are believed to be associated with faulting in their respective basin-like structures. Additional earthquakes of epicentral intensit y V occurred on December 11, 1969, near Richmond, Virginia (37.8° N 77.4°W) and on March 15, 1991, west of Richmond in Goochland County, some 37 km south-southwest of the site (Reference 35).The 1875 shock was probably felt in the vicinity of the site, with an intensity approaching V. The 1774 shock cannot be accurately projected to the site area because of the lack of information, but it is believed that ground motion at the site did not exceed a few percent of gravity. The 1969 shock was perceptible over a 3500 square-mile area. A study of the recent land forms in the site area does not reveal any adverse features such as faulting, slides, or areas of instability or brecciation that could have been caused by these shocks or from earlier earthquake shocks.Additional details on seismic history ar e found in Appendix A to the North Anna Power Station Units 1 and 2 PSAR.2.5.2.2.1 Microearthquake MonitoringDames & Moore's geologic investigati on of the f ault zone at the North Anna Power Station indicated that the zone had not e xperienced movement for the past 500,000 years, and was not in a critical state (Reference 1). None of the historic earthquakes in the Piedmont Province are known to have caused faulting at or n ear the surface. The fault zone underlying the reactor containment buildings and the fault z one underlying the North Anna dam appear to be of limited extent, and not structurally related to, or a continuation of, any known fault. No seismic activity, either instrumentally recorded or historically determined, can be shown to have any direct tectonic relationship to these fault zones. The closest zone of activity is 30 miles (48 km) south of the lake (Central Virginia Seismic Zone). No topographic expression of recent faulting has been observed in the vicinity of the lake. Due to the absence of definite earthquake-tectonic correlations for the region, it is not surprising that no activity was found associated with the fault zone, nor associated with the impoundment of Lake Anna.As a means of demonstrating this observation, the NRC required confirmatory microearthquake monitoring of the area around the site and Lake Anna. Phase I and Phase II (permanent) monitoring occurred at the site between January 21, 1974 through August 1, 1977. No microearthquake detected in the three and one-half years of monitoring was associated either with the fault onsite or related to the impoundment of Lake Anna. Four st ations of the original Revision 8-06/14 North Anna ISFSI SAR 2-3017-station monitoring network were incorporated into Virginia Tech's Central Virginia Monitoring Network for the specific purpose of monitoring any changes in seismicity in the region of the North Anna Power Station. To date, no change s have been observed that would contradict the conclusions reached in 1977 regarding the lack of association of microearthquakes with Lake Anna or with the fault at the North Anna Power Station (Reference 36).2.5.2.3 Design Basis Earthquake The North Anna Power Station Units 1 and 2 Preliminary Safety Analysis Report and design were completed prior to the promulgation of Appendix A to 10 CFR 100. Consequently, the term "design-basis earthquake," as used in this report, has the me aning it had prior to December 1973 when Appendix A to 10 CFR 100 became effective.

The design basis earthqu ak e (DBE) for the North Anna Power Station Units 1 and 2 was established by assuming that an ear thquake equivalent to the largest shock associated with the Arvonia Syncline might oc cur close to the North Anna site area. With th e epicenter of a shock similar to the 1875 MM I-VII moved to the vicinity of the site, it was estimat ed that the maximum horizontal ground acceleration at rock surface would be less than 0.12g.Accordingly, the design basis earthquake for Seismic Class I structures founded on rock w as established as 0.12g for horizontal ground motion, and two-thirds (0.08g) that value for vertical ground motion.For Seismic Class I structures founded on rock, analyses for earthquake mo tion were made using response spectra developed by enveloping the response spectra, for various degrees of damping, of the east-west and north-south components of the Helena (1935) earthquake and the southeast component of the Golden Gate record of the San Francisco (1957) earthquake, all normalized to 0.12g for the DBE. For Seismic Class I structures founded on saprolite more than 15 feet thick, these analyses fo r earthquak e motion were normaliz ed to 0.18g for the DBE to provide for calculated amplification through the overburden. The response spectra are shown on Figures 2.5-12 and 2.5-14 of the North Anna Power Station UFSAR.The amplification of earthquake motion th rough the overburden was computed using a lumped-mass spring system with model superposition.Based on the two-to-three puls es of strong ground motion for the San Francisco, California (1957), and Helena, Montana (1935

Revision 8-06/14 North Anna ISFSI SAR 2-32 2.5.5 Slope Stability The ISFSI site will utilize both cut and fill to obtain final grad

1 through 28; Compiled and edited by Seismological Observatory at Virginia Polytechnic Institute and State University, Blacksburg, Virginia (1977 through 1993).36.Summary Report of Microear thquake Monitoring at North Anna Power Station, January 24, 1974 through August 1, 1977, Dames & Moore, 1977.37.Chapman, M.D. and Krimgold, F., 1994; Seismi c Hazard Assessment for Virginia; Report for Virginia Department of Emergency Services and Federal Emergency Management Agency, Virginia Tech Seismic Obs., 62p.38.Martin, J. R., 1994; Soil Failure/Liquef action Susceptibility Analysis F or North Anna Power Station Seismic Mar gin Assessment.39.Geotechnical Report, North Anna Unit 3 - Site Separation Pr oject, Louisa County, Virginia; Bechtel Power Cor poration, December 2009.

Revision 8-06/14 North Anna ISFSI SAR 2-35Table 2-1DISPERSION FACTORS (/Q) IN ACCORDANCE WITH RE GULATORY GUIDE 1.145 Sector Distance (meters)/Q (sec/m 3)N 2033 6.61 x 10-5 NNE 2113 6.85 x 10-5 NE 2055 7.74  x 10-5 ENE 1867 6.45  x 10-5 E 1606 1.16  x 10-4 ESE 1335 2.01  x 10-4 SE 1100 3.15  x 10-4 SSE 948 1.77  x 10-4 S 847 1.10  x 10-4 SSW 818 1.03  x 10-4 SW 836 9.30  x 10-5 WSW 919 8.43  x 10-5 W 1067 8.53  x 10-5 WNW 1281 7.04  x 10-5 NW 1556 5.24  x 10-5 NNW 1820 4.42  x 10-5 Revision 8-06/14 North Anna ISFSI SAR 2-36Table 2-2  

OF USGS GAUGING STA TION RECORDS AND ESTIMATED STREAM FLOW DATA FOR THE NORTH ANNA DAMRiver Location Drainage Area (sq.mi.)Period of Record aDischarge (cfs)Average Minimum MaximumUSGS gauge at Doswell 439 1929-1971 382 b 1 c 24,800 dUSGS gauge at Doswell 439 1972-1992 399 e 35.5 f 23,300 g North Anna Dam 343 1929-1971 300 h l h 19,500 h North Anna Dam 343 1978-1999 288 i 25 j 11,700 ka.Dam was closed January 1972.b.Average discharge for 41-year period.c.Date of discharge: September 30 to October 2, 1932.d.Date of discharge: August 21, 1969.e.Average discharge for 21-year-period since 1971.f.Date of Discharge: October 8, 1991.g.Date of Discharge: June 22, 1972.h.Estimated.

i.Average Discharge since Partlow gauge has been in operation.

j.Date of Discharge: August 1, 1988.k.Date of Discharge: February 26, 1979.References 3 , 4 and 5 Revision 8-06/14 North Anna ISFSI SAR 2-37Table 2-3 FLOODS ON THE NORTH ANNA RIVER Flood PeriodPeak Flow at Doswell (cfs)Volume of Direct Runoff at Doswell (acre-feet)

August 12, 1928 18,400-April 24-29, 1937 18,300 81,400 October 17, 1943 11,600-August 12-25, 1955 12,400 54,700 August 20-23, 1969 24,800 141,000 June 20-22, 1972 23,300 107,200 Sept. 21-30, 1975 11,600 77,870Feb. 22-March 3, 1979 11,700 73,131March 27-April 3, 1984 11,700 78,229Nov. 1-11, 1985 10,700 55,625March 27-April 2, 1994 12,000 85,600 Sept. 5-13, 1996 11,600 61,380l.References 3 , 4 and 5 Revision 8-06/14 North Anna ISFSI SAR 2-38Table 2-4 RECOVERY AND RQD VALUES OF BORINGS Boring No.Run No.From (F eet)To (Feet)Inches RecoveredRecovery Percent Percent RQD F-4 1 49.1 54.1 13 21.6 0 2 54.1 59.1 47 78.3 40 F-5 1 64.5 69.5 0 0 0 2 69.5 74.5 8 13.3 0 3 74.5 79.5 2 3.3 0 4 79.5 84.5 0 0 0 5 84.5 89.5 4 6.6 0 6 89.5 94.5 0 0 0 7 94.5 99.5 0 0 0 8 99.5 104.5 0 0 0 9 104.5 109.5 30 50 0 10 109.5 114.5 48 80 0 F-6 1 44.0 49.0 0 0 0 2 49.0 54.0 0 0 0 3 54.0 59.0 42 70 18.3 F-7 1 75.0 80.0 0 0 0 2 80.0 85.0 0 0 0 3 85.0 90.0 0 0 0 4 90.0 95.0 2 3.3 0 5 95.0 100.0 0 0 0 6 100.0 105.0 38 63 0 F-8 1 64.2 69.2 48 80 0 F-9 1 59.1 64.1 0 0 0 2 64.1 69.1 0 0 0 3 69.1 74.1 7.5 12.5 0 4 75.0 80.0 28.5 47 7.5 5 80.0 85.0 12 20 6.6 6 85.0 90.0 0 0 0 7 90.0 95.0 8 13 0 8 95.0 100.0 19 31 6.6 9 100.0 105.0 36 60 17.5 F-10 1 69.0 74.0 57 95 35.8 Revision 8-06/14 North Anna ISFSI SAR 2-39 F-11 1 39.0 44.0 6 10 0 2 44.0 49.0 8 13.3 0 3 49.0 54.0 14 23 0 4 54.0 59.0 42 70 0 5 59.0 64.0 35 58 28 6 64.0 69.0 42 70 22.5Table 2-4 (CONTINUED)

Revision 8-06/14 North Anna ISFSI SAR 2-55 Figure 2-10SITE GEOLOGICAL MAP Revision 8-06/14 North Anna ISFSI SAR 2-56 Figure 2-11 ISFSI BORING LOCATIONS Revision 8-06/14 North Anna ISFSI SAR 2-57 Figure 2-12ISFSI SUBSURFACE CROSS SECTION Revision 8-06/14 North Anna ISFSI SAR 2-58 Figure 2-13REGIONAL GEOLOGIC MAP Revision 8-06/14 North Anna ISFSI SAR 2-59 Figure 2-14PAD #1 SURFACE PROFILE Revision 8-06/14 North Anna ISFSI SAR 2-60 Figure 2-15PAD #2 SURFACE PROFILE Revision 8-06/14 North Anna ISFSI SAR 2-61 Figure 2-16PAD #3 SURFACE PROFILE Revision 8-06/14 North Anna ISFSI SAR 2-62 Figure 2-17EARTHQUAKE LOCATIONS

Revision 8-06/14 North Anna ISFSI SAR 2-64 Figure 2-19ALTERNATE TRANSPORT ROUTE SUBSURFACE CROSS SECTIONS Revision 8-06/14 North Anna ISFSI SAR 2A-iAppendix 2A Boring Logs Revision 8-06/14 North Anna ISFSI SAR 2A-ii Intentionally Blank Revision 8-06/14 North Anna ISFSI SAR 2A-1 (1994 BORINGS)FIELD EXPLORATION PROCEDURES Disturbed SamplingSoil test borings were drilled and tested in accordance with ASTM D 1452 and ASTM D 1586 procedures with a CME-55 truck m ounted drill rig, by mechanically advancing hollow stem auger flights into the ground. At regular intervals, the plug was removed from the auge r head, and soil samples were obtained with a standard 1.4"I.D., 2"O.D., 20" long split tube sampler. The sampler was attached to the end of "A" size drill rods and lowered th rough the augers to sampling elevation. The sampler was first seated to pene tration loose cuttings and disturbed soil, then driven an additional foot with blows of a 140 lb. hammer falling 30".

The sampler was then extracted from the soil, the plug reinserted into the auger head, and the auger advanced to the next sampling elevation. The number of blows required to drive the sampler each 6" increment of penetration was recorded and is shown on the bor ing logs. The number of blows required to drive the sampler the final foot is termed the "penet ration resistance". Penetration resistance, when properly evaluated, is an index to soil density, strength, and foundation support capacity.

Undisturbed SamplingSplit tube samples are suitable for visual examination and classification tests but are not sufficiently intact for quantitative laboratory testing. Relatively undisturbed samples were obtained by forcing sections of 3"O.D., 16 gauge, steel tubing into the soil at the desired sampling levels. This sampling procedure is described by ASTM Specification D-1587. Each tube, together with the encased soil, was carefully removed from the ground, made airtight , and transported to the laboratory. Locations and de pths of undisturbed samples are shown on the test boring records.

Revision 8-06/14 North Anna ISFSI SAR 2A-2ROCK CORING PROCEDURESRock coring procedures are used to evaluate subsurface conditions below the depth of auger refusal. Auger refusal typical ly reflects the presence of obs tructions (e.g., boulders) or the presence of bedrock.Water is used to drill a diamon d studded drill bit through bedroc k or obstructions. The drill pipe at the bottom of the boring cont ains a steel sleeve, or core barrel , that accepts the drill core as the bit is advanced. Typically, the core barrel can accommodate 5 or 10 feet of core. When bedrock is encountered, a run numbe r is designated each time the core barrel is filled with sample and removed from the boring.The percent of recovery is calc ulated for every run. Percent recovery is the ratio of the recovered length of core to the length of the core run.

The rock quality designation (RQD) is calculated for each co re run when N-sized core sampling procedures are used. N-si zed core is approximately 2-in ches in diameter. The RQD is the ratio of the cumulative length of core greate r than 4-inches long and the length of core run. The RQD is often used to evaluate the engineering properties of bedrock.

Revision 8-06/14 North Anna ISFSI SAR 2A-3KEY TO BORING LOG SOIL CLASSIFICATIONSSoils IdentificationASTM SOIL CLASSIFICATION IS BASED ON THE DISTRIBUTION OF THE SAND AND GRAVEL SEED PARTICLES, THE PLASTICITY (E.G. ATTE RBERG LIMITS) OF THE FINE SAND, SILT AND CLAY FRACTION, AND THE RELATIVE DENSITY/CONSISTENCY AS DETERMINED FROM THE STANDARD PENETRATION TEST N-VALUE.NOTE: Particle Size is Designated by U.S. Standard Sieve Sizes.Relative Density or ConsistencyTHE STANDARD PENETRATION TEST N-VALUES ARE USED TO EVALUATE THE RELATIVE DENSITY OF COARSE-GRAINED SOILS OR THE CONSISTENCY OF FINE-GRAINED SOILS.Soil TypeParticle Size Boulder 12 in.Cobble 3 - 12 in.Gravel-Coarse 3/4 - 3 in.-Fine#4 - 3/4 in.Sand-Coarse

#10 - #4-Medium#40 - #10-Fine#200 - #40Silt (non-cohesive)

<#200RELATIVE DENSITYCONSISTENCYTermN-ValueTermN-ValueVery Loose 0-4Very Soft 0-1 Loose 5-9 Soft 2-4 Medium Dense10-30 Firm 5-8 Dense31-50Stiff 9-16Very DenseOver 50Very Stiff17-30 Hard31-50Very HardOver 50 Revision 8-06/14 North Anna ISFSI SAR 2A-4 Revision 8-06/14 North Anna ISFSI SAR 2A-5 Revision 8-06/14 North Anna ISFSI SAR 2A-6 Revision 8-06/14 North Anna ISFSI SAR 2A-7 Revision 8-06/14 North Anna ISFSI SAR 2A-8 Revision 8-06/14 North Anna ISFSI SAR 2A-9 Revision 8-06/14 North Anna ISFSI SAR 2A-10 Revision 8-06/14 North Anna ISFSI SAR 2A-11 Revision 8-06/14 North Anna ISFSI SAR 2A-12 Revision 8-06/14 North Anna ISFSI SAR 2A-13 Revision 8-06/14 North Anna ISFSI SAR 2A-14 Revision 8-06/14 North Anna ISFSI SAR 2A-15 Revision 8-06/14 North Anna ISFSI SAR 2A-16 Revision 8-06/14 North Anna ISFSI SAR 2A-17 Revision 8-06/14 North Anna ISFSI SAR 2A-18 Revision 8-06/14 North Anna ISFSI SAR 2A-19 Revision 8-06/14 North Anna ISFSI SAR 2A-20 Revision 8-06/14 North Anna ISFSI SAR 2A-21 Revision 8-06/14 North Anna ISFSI SAR 2A-22 Revision 8-06/14 North Anna ISFSI SAR 2A-23 Revision 8-06/14 North Anna ISFSI SAR 2A-24 Revision 8-06/14 North Anna ISFSI SAR 2A-25 Revision 8-06/14 North Anna ISFSI SAR 2A-26 Revision 8-06/14 North Anna ISFSI SAR 2A-27 Revision 8-06/14 North Anna ISFSI SAR 2A-28 Revision 8-06/14 North Anna ISFSI SAR 2A-29 Revision 8-06/14 North Anna ISFSI SAR 2A-30 Revision 8-06/14 North Anna ISFSI SAR 2A-31 Revision 8-06/14 North Anna ISFSI SAR 2A-32 Revision 8-06/14 North Anna ISFSI SAR 2A-33 Revision 8-06/14 North Anna ISFSI SAR 2A-34 Revision 8-06/14 North Anna ISFSI SAR 2A-35 Revision 8-06/14 North Anna ISFSI SAR 2A-36 Revision 8-06/14 North Anna ISFSI SAR 2A-37 Revision 8-06/14 North Anna ISFSI SAR 2A-38 Revision 8-06/14 North Anna ISFSI SAR 2A-39 Revision 8-06/14 North Anna ISFSI SAR 2A-40 Revision 8-06/14 North Anna ISFSI SAR 2A-41 2008 BORINGS Revision 8-06/14 North Anna ISFSI SAR 2A-42 Revision 8-06/14 North Anna ISFSI SAR 2A-43 Revision 8-06/14 North Anna ISFSI SAR 2A-44 Intentionally Blank Revision 8-06/14 North Anna ISFSI SAR 2B-iAppendix 2BLaboratory Tests Revision 8-06/14 North Anna ISFSI SAR 2B-ii Intentionally Blank Revision 8-06/14 North Anna ISFSI SAR 2B-1 PHASE 2 - ISFSI NORTH ANNA POWER STATION - MINERAL, VIRGINIA VIRGINIA PO WER F&R #V60-073LABORATORY TEST RESULTSBoringF-5A F-5 F-6 F-6F-6F-7A F-7ASample No.

UD-1 S-7 S-2 S-5S-9 UD-l UD-2 Depth (ft.)

18.0-20.0 19.0-20.5 1.5-3.0 9.0-10.5 29.0-30.5 4.0-6.0 16.0-18.0Gradation % Passing Sieve No. 4............100 100....100 No. 10 100 100 100 97.9 99.9 100 99.8 No. 40 92.5 96.1 96.6 84.4 77.8 96.8 83.1 No. 100 67.7 79.5 90.3 61.7 35.9 77.9 50.8 No. 200 53.9 70.2 87.9 54.3 24.8 72.0 38.0 Liquid Limit (%)

...65 85 62...84...Plasticity Index

...19 31 19...30...Natural Moisture (%)

53.3 55.7 37.4 29.0 29.3 34.1 31.8ASTM Classification

...MH MH MH...MH...

Revision 8-06/14 North Anna ISFSI SAR 2B-2 PHASE 2 - ISFSI NORTH ANNA POWER STATION - MINERAL, VIRGINIA VIRGINIA PO WER F&R #V60-073LABORATORY TEST RESULTSBoring F-7 F-7 F-8 F-8 F-9A F-9 F-10Sample No.

S-7 S-18 S-4 S-7 UD-1 S-13 S-3 Depth (ft.)

19.0-20.5 74.0-74.8 9.0-10.5 19.0-20.5 4.0-6.0 49.0-50.5 3.0-4.5Gradation % Passing Sieve 3/8 inch.....................No. 4 100 100 100 100 100 100 100 No. 10 98.6 97.6 99.9 99.9 99.8 97.7 99.7 No. 40 80.7 70.7 93.1 84.9 84.3 78.8 69.0 No. 100 60.8 47.2 81.3 64.4 52.3 39.3 44.5 No. 200 53.1 34.2 76.3 51.2 44.9 26.2 36.8 Liquid Limit (%)

60 40 58...64...46Plasticity Index 16 6 26...18...15Natural Moisture (%)

30.3 25.4 34.7 27.0 27.1 22.7 13.6ASTM Classification MH SM MH...SM...SM Revision 8-06/14 North Anna ISFSI SAR 2B-3 PHASE 2 - ISFSI NORTH ANNA POWER STATION - MINERAL, VIRGINIA VIRGINIA PO WER F&R #V60-073LABORATORY TEST RESULTSBoring F-10 F-10 P-2 P-3P-4Sample No.

S-5 S-10 BAG BAG BAG Depth (ft.)

9.0-10.5 34.0-35.5 0.0-5.0 0.0-5.0 0.0-5.0Gradation % Passing Sieve 3/8 inch...100 100......No. 4 100 99.2 98.7 100 100 No. 10 99.4 90.9 94.8 99.4 99.1 No. 40 65.4 55.4 81.1 83.5 90.9 No. 100 41.5 33.9 57.8 67.7 64.9 No. 200 31.6 24.8 49.5 62.1 55.7 Liquid Limit (%)

14.9 22.1 8.5 15.0 8.5ASTM Classification SM...SC CH ML Revision 8-06/14 North Anna ISFSI SAR 2B-4*Sample was molded at natural moisture content and unit weight.

PHASE 2 - ISFSI NORTH ANNA POWER STATION - MINERAL, VIRGINIA VIRGINIA PO WER F&R #V60-073CBR TEST RESULTS Boring P-2 P-3 F-7A Sample No.

BulkBulkComposite Depth (ft.)

0.0-5.0 0.0-5.0 16.0-22.0ASTM Classification SC CH SMMoisture-Density Relationship Test Maximum Dry Density (pcf) 117.5 111.2 109.0*Optimum Moisture (%)

12.4 16.6 35.0*CBR (Unsoaked)

CBR (Soaked) 39.2 7.6 38.9 7.3 6.4 NA Revision 8-06/14 North Anna ISFSI SAR 2B-5 Revision 8-06/14 North Anna ISFSI SAR 2B-6PARTICLE SIZE ANALYSIS TESTObjective:The grain size data are used to aid in the classification of soils and in the estimation of soil behavior.