| title = Indian Point, Units 2 and 3 - 2010 Year Class Report for the Hudson River Estuary Monitoring Program

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{{#Wiki_filter:   Dynegy Roseton L.L.C. - Debtor in Possession   Entergy Nuclear Indian Point 2 L.L.C. Entergy Nuclear Indian Point 3 L.L.C. GenOn Bowline L.L.C.                                                  

i __________ Page  LIST OF FIGURES ........................................................................................................... iii LIST OF TABLES ............................................................................................................. x  1. INTRODUCTION......................................................................................................... 1-1   

: 2. MATERIALS AND METHODS ..................................................................................... 2-1 2.1 Sampling Design ............................................................................................... 2-1  2.2 Longitudinal River Ichthyoplankton Survey ........................................................ 2-2 2.2.1 Field Methods ........................................................................................ 2-2  2.2.2 Laboratory Methods ............................................................................... 2-4 2.3 Fall Juvenile Survey .......................................................................................... 2-6 2.3.1 Field Methods ........................................................................................ 2-6  2.3.2 Laboratory Methods ............................................................................... 2-8 2.4 Beach Seine Survey .......................................................................................... 2-8 2.4.1 Field Methods ........................................................................................ 2-8  2.4.2 Laboratory Methods ............................................................................... 2-9 2.5 Analytical Methods ............................................................................................ 2-9 2.5.1 Physical/Chemical Parameters .............................................................. 2-9  2.5.2 Spatiotemporal Distribution Indices ....................................................... 2-11 

: 3. PHYSICAL/CHEMICAL PARAMETERS ...................................................................... 3-1 3.1 Green Island Dam Flows ................................................................................... 3-1 3.2 Hudson River Water Temperatures near Poughkeepsie ................................... 3-1  3.3 Hudson River Surveys....................................................................................... 3-1 

: 4. SPATIOTEMPORAL DISTRIBUTION OF SELECTED SPECIES  OF HUDSON RIVER ESTUARY FISHES ................................................................... 4-1 4.1 Species Collected ............................................................................................. 4-1  4.2 Striped Bass...................................................................................................... 4-1  4.3 White Perch ...................................................................................................... 4-2  4.4 Atlantic Tomcod ................................................................................................ 4-2  4.5 Bay Anchovy ..................................................................................................... 4-2 Page  ii __________  4.6 American Shad ................................................................................................. 4-3  4.7 River Herrings ................................................................................................... 4-3  4.8 Alewife  .............................................................................................................. 4-3  4.9 Blueback Herring .............................................................................................. 4-4  4.10 Gizzard Shad .................................................................................................... 4-4  4.11 Rainbow Smelt .................................................................................................. 4-4  4.12 Hogchoker ........................................................................................................ 4-4  4.13 Spottail Shiner ................................................................................................... 4-5  4.14 Atlantic Sturgeon ............................................................................................... 4-5  4.15 Shortnose Sturgeon .......................................................................................... 4-5  4.16 White Catfish .................................................................................................... 4-5  4.17 Weakfish ........................................................................................................... 4-6  4.18 Bluefish ............................................................................................................. 4-6  REFERENCES CITED AND PREVIOUS YEAR CLASS REPORTS ................................. R-1 APPENDIX A: QUALITY CONTROL REPORT FOR THE 2010 HUDSON RIVER  ICHTHYOPLANKTON LABORATORY PROGRAM AND 2010 FALL  JUVENILE SURVEY APPENDIX B: PHYSICAL/CHEMICAL PARAMETERS APPENDIX C: NUMBERS OF FISH COLLECTED IN THE LONG RIVER (1988-2010),  FALL SHOALS (1985-2010), AND BEACH SEINE (1985-2010) SURVEYS APPENDIX D: ANNUAL ABUNDANCE INDICESAPPENDIX E: DENSITY AND STANDING CROP ESTIMATES APPENDIX F: LENGTH FREQUENCY DISTRIBUTION

This report adds to the historical database by presenting the results of the Longitudinal River Ichthyoplankton Survey, the Fall Juvenile Survey (formerly, the Fall Shoals Survey), and the Beach Seine Survey for 2010. However, the format of this report differs from previous years in that it is primarily data, supplying summarizing figures and tables without the accompanying text. The 2010 Year Class Report presents basic abundance and distribution data with the following objectives:  

Present patterns in growth for the 2010 year class of key species.

Appendix A Quality Control Report for the 2010 Hudson River Ichthyoplankton Laboratory Program and 2010 Fall Juvenile Survey;  Appendix B Physical/Chemical Parameters;   Appendix C Numbers of Fish Collected in the Long River (1988-2010), Fall Juvenile (1985-2010), and Beach Seine (1985-2010) Surveys;   Appendix D Annual Abundance Indices;   Appendix E Density and Standing Crop Estimates; and  Appendix F Length Frequency Distribution.

Link to Chapter 2 Table 1-1  Fish Species Treated in Depth in the 2010 Year Class Report  

Common Name Scientific Name1 Alewife American shad Atlantic sturgeon Atlantic tomcodBay anchovyBlueback herringBluefish Gizzard shad Hogchoker Rainbow smeltShortnose sturgeonSpottail shinerStriped bass Weakfish White catfish White perch   

__________ 1. Names listed in Nelson et al. 2004.  

__________   That portion of the Hudson River estuary extending from the shore to a depth of 10 ft (the stratum defined only for BSS). That portion of the Hudson River estuary extending from the shore to a depth of 20 ft at mean low tide.

That portion of the Hudson River estuary extending from the bottom to 10 ft above the bottom where river depth is greater than 20 ft at mean low tide.

That portion of the Hudson River estuary not considered bottom where river depth is greater than 20 ft at mean low tide. The relative area and configuration of the shoal, bottom, and channel strata vary over the length of the Hudson River estuary but may be characterized using the three cross section views presented in Figure 2-2. For example, the low relief sectional is characteristic of the Tappan Zee and Croton-Haverstraw regions, the high relief sectional is exemplified by the Yonkers and Poughkeepsie regions, and the fjord relief sectional represents the West Point region.  

__________ yolk-sac larvae (PYSL). The second effort, performed during April, focused on the collection of American shad eggs. The third effort, from late April to mid-May, was designed to collect eggs of  spp. and American shad. The fourth effort, performed from mid-May through early June, targeted spp. and American shad yolk-sac larvae (YSL). The fifth effort, in June and early July, was designed to collect spp. and American shad PYSL. The LRS sampling program concluded with a 13-week period, sampled biweekly, from the middle of July to early October. The final sampling effort was designed to collect all life stages of bay anchovy.  

The allocation of sampling effort among regions and strata is presented in Table 2-3. Of the 3522 ichthyoplankton samples scheduled for collection during 2010, 3519 samples were collected, accounting for 99.9 percent of the scheduled total.   

Two distinct gear types were used for field collections during the 2010 LRS:  1.0-m2 Tucker trawl (Figure 2-4 and Table 2-4) to sample the shoal and channel strata (non-bottom), and  1.0-m2 epibenthic sled (Figure 2-5 and Table 2-4) to sample the bottom-only shoal and channel strata.

Both gear types were towed against the prevailing current for 5 minutes. The tow started with the remote opening of the net and terminated with its remote closing. If the river depth was 20 ft or less, an open set and retrieval of the net was performed. The tow speed for the Tucker trawl was adjusted to maintain a towing wire angle of approximately 45o averaging approximately 0.9 m/second. The tow speed for the epibenthic sled-mounted net was maintained at approximately 1.0 m/second. An electronic flowmeter mounted along the side of the research vessel and equipped with an on-deck readout display was used to establish and maintain tow speed. A calibrated digital flowmeter mounted in the center of the net mouth was used to calculate the volume of water filtered for each sample. Following deployment and retrieval of the sampling gear, net washing was performed to concentrate the sample into the codend bucket. The samples were then examined for yearling and older fish which were identified, enumerated, and returned to the Hudson River estuary.

measurements of water temperature (°C), dissolved oxygen (mg/L), and specific conductance (microsieman/cm at 25°C) were taken with calibrated meters at fixed river mile and strata stations in conjunction with the biological sampling. The number of physical/chemical sampling locations, by river mile and strata, are presented in Table 2-5 for the 2010 LRS. Physical/chemical measurements were recorded from surface, mid-depth, and bottom water depth at channel stations and from the surface and bottom water depth at shoal stations. During the 23 collection weeks of the 2010 LRS, 3520 physical/chemical measurements were scheduled and 3519 measurements were actually recorded, accounting for nearly 100 percent of the scheduled total.

__________   In 2010, approximately 70 percent of the regular LRS samples were selected for laboratory analysis. Selection of samples for laboratory analysis began with the grouping of samples according to river run (i.e., sampling week), region, and strata. Based on these groupings, samples were selected based on one of the following criteria:

: 1. If there were less than 6 samples in the group, then all were selected for analysis. 2. If there were between 6 and 12 samples in the group, then 50 percent of the samples were randomly selected for analysis.

: 3. If there were more than 12 samples in the group, then 20 percent of the samples were randomly selected for analysis. The allocation of samples for laboratory analysis among regions, strata, and gear types based on these criteria is listed in Table 2-6. The total number of analyzed samples for 2010 was 2440, comprising 69.3 percent of the collected samples.

Two different sets of criteria were used for subsampling of larval stages, depending on the river run. Beginning with the river run in which striped bass PYSL first appeared, and for the next 8 river runs (a total of 9 consecutive river runs), a minimum of 500 larvae (i.e., the combined total of YSL, PYSL, and YOY of striped bass, white perch, and unidentified ) was sorted from the entire sample and a minimum of 50 non- larvae was also sorted. Because some of the more difficult distinctions between species (e.g., striped bass versus white perch) or between life stages could not be made reliably during sorting, samples from these 9 river runs were typically sorted in their entirety for larvae (i.e., YSL, PYSL, and YOY combined) of all species combined. An exception to this may have been made, at the discretion of the laboratory supervisor, under the following circumstances:  when extremely large numbers of non-larvae occurred in the sample and a qualified identifier had verified that sufficient numbers of both  larvae and non- larvae were sorted to meet their respective subsampling quotas. The purpose of this exception was to allow splitting before sorting of taxa such as clupeids which could readily be distinguished from  by sorters.

__________ by a continuous sampling plan, shown in Figure 2-7 (CSP-V from MIL-STD-1235, AOQL = 10 percent).

E                E                E where O1, O2, and O3 = Observed counts for splits 1, 2, and 3. E = Expected value for the sample (average of O1, O2, and O3). If the calculated value for chi-square was less than 5.99, then the splits of that sample were considered random, and the sample passed the split QC (5.99 was the critical value of chi-square with two degrees of freedom at an alpha level of 0.05). If a sample was split for both eggs and larvae, then both stages were tested separately. The sample passed the split QC only if chi-square was below the critical value for both life stages.  

Eggs and larvae were separated from detrital material, sorted by major taxonomic group and life stage, counted, and placed in vials containing 5 percent formalin or in ethyl alcohol. Sorted samples were evaluated by a trained technician under magnification and all organisms were identified and enumerated. The following life stage designations were used in identification:

Life Stage                                     Description Egg Embryonic stage from spawning to hatching, YSL From hatching to development of a complete and functional digestive system, PYSL From development of a complete digestive system to transformation to juvenile form, and YOY From completed transformation to Age 1.

Whenever possible, a maximum of 30 striped bass, 30 white perch, 30 American shad, 30 Atlantic tomcod, and 30 bay anchovy per sample were measured. Organisms were chosen at random from each taxon regardless of life stage until the required numbers were obtained; life stages to be included were YSL, PYSL, and YOY. The total length of YSL and PYSL was measured to the nearest 0.1 mm and to the nearest 1 mm for YOY. Measurements were recorded on the laboratory data sheet. Selection of specimens for measuring was randomized by spreading them uniformly in a gridded container, selecting a starting point in the grid by means of a random number table, and then measuring the first 30 measurable specimens encountered in a predetermined pattern commencing at the starting point. Every grid space had an equal probability of being selected as the starting point, so every specimen had an equal probability of being included in the subsample.

__________ Continuous sampling inspection was employed during the sort and identification procedures to ensure an average outgoing quality limit of 10 percent or better. Two sampling modes were required in the continuous sampling plan (CSP-1):

The first eight samples sorted or analyzed for larval identification by an individual are subject to 100 percent QC reanalysis. If all eight pass the reanalysis, i.e., if <10 percent of the ichthyoplankton are missed or misidentified per sample, the individual is placed in CSP Mode 2. If any sample fails during Mode 1, then Mode 1 is continued until eight consecutive samples pass. For example, if a sample with QC No. 7 fails, then samples with QC Nos. 8 through 15 are subject to QC resorting. Lots of seven consecutive samples per individual are assigned for identification QC and per laboratory facility for sort QC. One sample from each lot is randomly chosen for QC analysis. If a sample fails (>10 percent of organisms missed or misidentified) during Mode 2, the individual is placed back into Mode 1.

For example, if a sample with QC No. 6 fails in a lot of seven samples, then samples with QC Nos. 7 through 14 are subject to QC reanalysis. If samples 7 through 14 pass, the individual is again placed in Mode 2.

Results of the 2010 CSP-1 Quality Control Program are contained in Appendix A.

The 2010 FJS biweekly sampling program extended from RM 1 to 152 and covered 22 weeks from 5 July to 5 December (Figure 2-3). Samples were collected at night for the first 8 river runs from 5 July through 17 October, and during the day for last 3 river runs from 18 October through 5 December. These last river runs, which were conducted with a modified sampling design, were intended to examine Atlantic tomcod distribution. Table 2-7 presents the distribution of the FJS sampling effort among the 13 river regions by stratum. Of the 2130 samples scheduled for collection, 2130 were actually collected, yielding 100 percent completion.  

The quota was to be 20 specimens of a selected species from each river region per river run; because of the necessity of returning fish to the river alive, the first 20 specimens of a selected species were brought to the laboratory for length measurements. The Hyde Park through Albany regions were considered one region for the purpose of filling length measurement quotas during the entire FJS and during River Runs 4 through 10 of the BSS. Also for the BSS during River Runs 1 through 3, the Yonkers through West Point regions were considered as one region for the same purpose. In river regions where fewer than 10 samples were collected per survey, no more than 10 specimens of each selected species from an individual sample were used to fill the length measurement quota. This criterion was used in the following surveys for the specified river regions:

Sampling Program         Region BSS  YK, IP, WP, CW, PK FJS  WP, PK In all other regions, when the sample schedule resulted in 10 or more samples per survey, no more than 5 specimens per species in a sample were used to fill the length measurement quotas. If more specimens of a species were collected than needed, the individuals used to fill the quotas were randomly selected.

Alewife  Shortnose sturgeon   American shad  Spottail shiner   Atlantic sturgeon  Striped bass   Atlantic tomcod  Weakfish   Bay anchovy  White catfish   Blueback herring  White perch.

The 2010 BSS utilized a 30.5-m (nominal 100 ft) total length beach seine to collect YOY fish in the shorezone of each region, except the Battery region. Table 2-9 presents specifications for the beach seine. One end of the net was held on shore and the other end was towed perpendicularly away from the shore by boat. The seine was then hauled, clockwise if possible, in a semicircular path toward shore. The complete beach seine deployment swept an area of approximately 450 m2 (TI 1981). All BSS samples were collected on a diurnal schedule during alternate weeks of the FJS.  

To display the spatial and temporal patterns of temperature, salinity, and dissolved oxygen, a mean of each parameter for each sampling location and sampling week, weighted by stratum volume, was calculated. Equation 1 was used to compute these means for the standard physical/chemical stations sampled in conjunction with the LRS and FJS. Equation 2 was used for data collected in conjunction with the BSS. Salinity data were computed from conductivity data (microsieman/cm at 25&deg;C) using Equation 3 (TI 1976). This equation differs from that used in some of the previous Year Class reports in that pressure data are not required. The maximum deviation between this equation and the previous equation is 0.1 percent (TI 1976).                             nlw                        nklw               ndklw  Wlw =      Pkr [  1/nklw    ( 1/ndklw      Widklw )] (1)                          k=1                         d=1                   i=1 where Wlw = Weighted mean of a physical/chemical parameter at sampling location l during week w of the LRS and FJS. Widklw = Physical/chemical measurement for location i at depth d in stratum k at sampling location l during week w.

__________   Pkr = Proportion of the river volume of region r containing sampling location l that is contained by stratum k (bottom and channel strata were combined for water quality analysis).

nklw = Number of depths sampled in stratum k at sampling location l during week w.

nlw = Number of strata sampled at sampling location l during week w.

nrw   Wrw =  1/ nrw         Wirw (2)                i=1 where  

Wrw = Mean of a physical/chemical parameter at river mile r during   biweek w of the BSS.  

Wirw = Physical/chemical measurement for location i at river mile r    during biweek w. nrw = Number of physical/chemical measurements taken at river mile r    during biweek w. Salinity =  -100  ( 1 - C25/178.5) (3) where  

C25 = Conductivity (millisieman/cm at 25&deg;C).

__________      Estimates of population densities were made for the LRS and FJS. For the LRS and FJS, the number of fish (by species and life stage) captured in individual samples was first converted to density (no./m3 of water sampled) using Equation 4. The mean density and the standard error of the mean were calculated for each stratum, region, and sampling week using Equations 5 and 6. To obtain a mean density and standard error for each region during each sampling week, the stratum densities were weighted by the proportion of the regional river volume found in the stratum (Equations 7 and 8). If a stratum was not sampled, its volume was added to the volume of an adjacent stratum that was sampled. Stratum volume adjustments were made according to the following rules:

Dikrw = Density (for a life stage and species)/m3 for sample i in stratum k    in region r during week w. Cikrw = Number of fish caught in sample i in stratum k in region r during week w.

Vikrw = Volume sampled (m3) by sample i in stratum k in region r during week w.

__________   SE(Dkrw) =        (6) where  

SE(Dkrw) = Standard error of the average density in stratum k in region r during week w.

Dikrw = Sample density calculated in Equation 4.

Pk* = Proportion of the regional river volume found in stratum k (Table 2-11). nrw = Number of strata sampled in region r during week w. SE(Drw) =            (8) where  

* When a stratum is missing, Pk for the sampled stratum is equal to the sum of the Pk for the sampled  stratum and the Pk for the unsampled stratum.

__________   Crw =    (9)  where  

Crw = Average CPUE in region r during week w.

SE(Crw) = Standard error of average CPUE in region r during week w.

Crw = Average regional CPUE calculated in Equation 9. An index of standing crop (the number of fish in an area at a particular time) was estimated by life stage and species for each of the three surveys. Standing crop indices and the associated standard errors were calculated for each stratum in a region by taking the product of the average stratum density (or the standard error) and the volume of water contained in that stratum (Equations 11 and 12 for the LRS and FJS) (Table 2-11). The regional standing crop index was then estimated as the sum of the stratum index values (Equations 13 and 14).

SCkrw = (Vkr)(Dkrw) (11) where  

Vkr = River volume contained by stratum k in region r.

__________     SE(SCkrw) = (Vkr)[SE(Dkrw)] (12) where  

3  SCrw** =    SCkrw (13)    k=1  where  

SCkrw = Stratum standing crop index calculated in Equation 11. SE(SC)rw **        =         (14)  where  SE(SCrw) = Standard error of standing crop index for region r during week w.

SE(SCw) = Standard error of standing crop index for week w. For the LRS and FJS, regional standing crop indices include the Battery Region (r=0).

SE(SCrw) = Standard error of regional standing crop index calculated in Equations 14 or 18.

An index of regional standing crop (and standard error) for the BSS was obtained by multiplying CPUE and the surface area of the shorezone and dividing by the empirically derived estimate of the area sampled by the 30.5-m beach seine (Equations 17 and 18). The weekly index of standing crop for the shorezone was calculated as the sum of the 12 regional standing crops (Equations 15 and 16).  

SCrw = (Crw Ar) / A (17) where  

SCrw = Standing crop index for the shorezone in region r during week w.

Crw = Average regional CPUE calculated in Equation 9.

Ar  = Surface area (m2) of the shorezone in region r.

A  = Surface area (m2) sampled by the beach seine (450 m2) (TI 1981).   

SE(SCrw) = [SE(Crw)] (Ar) (18)    ____________            A where

SE(SCrw) = Standard error of standing crop index for the shorezone in region r during week w.

SE(Crw) = Standard error of average regional CPUE calculated in Equation 10. Distribution indices were computed to facilitate presentation of changes in distribution of selected species and life stages through time and space. To allow comparisons of 2010 data

__________ with historical data, only data from samples collected from Weeks 18 to 26 (where Week 1 begins with the first Monday in January) were used for LRS (except for bay anchovy which used Weeks 18-40); data from Weeks 33 to 40 were used for the FJS and BSS. In all cases, data were used only when Regions 1-12 were sampled (except for bay anchovy which included Region 0).  

The periods used for the LRS and BSS spanned 1974-2010, whereas the time period for the FJS extended from 1979 (when the FJS sampled the river from RM 12 to RM 152) through 2010. Temporal and geographic indices for bay anchovy from the LRS used the period from 1988 to 2010, when the sampling design included the Battery region.

A temporal index that collapses data for the entire Hudson River estuary was computed for early life stages from LRS standing crop indices (Equation 20):   Twy    =            (20) where Twy = Temporal index for week w in year y.

__________   SCwy = Weekly standing crop index in year y calculated in Equation 15. ny = Number of weeks sampled in year y.

Link to Chapter 3 Figure 2-1. Location of 13 geographic regions (with river mile boundaries) sampled during the 2010 biological monitoring program in the Hudson River estuary.

__________ Table 2-1  Strata Sampled within the 13 Geographic Regions of the Hudson River Estuary                 During 2010 River                 2010 Surveys       Region        Abbreviation River Miles Kilometers Shore Shoal Channel Bottom Battery BT 1-11 1-19  -- -- X X Yonkers YK 12-23 19-39  X X X X Tappan Zee TZ 24-33 39-55  X X X X  Croton-Haverstraw CH 34-38 55-63  X X X X  Indian Point IP 39-46 63-76  X X X X West Point WP 47-55 76-90  X -- X X Cornwall CW 56-61 90-100 X X X X Poughkeepsie PK 62-76 100-124 X -- X X Hyde Park HP 77-85 124-138 X -- X X Kingston KG 86-93 138-151 X -- X X  Saugerties SG 94-106 151-172 X -- X X  Catskill CS 107-124 172-201 X -- X X Albany AL 125-152 201-246 X -- X X   

__________                                                             Table 2-2  Summary of 2010 Hudson River Surveys Sampling Schedule   Sample Number Program Phase Start Week End Week Number of River Runs Sampling Frequency Strata Sampled Collection Projected   Actual Lab Analysis Sampling Gear          Longitudinal River   Ichthyoplankton  Survey 15 MAR 10 OCT 23 Weekly/ Biweekly Shoal 588 587 555 1.0-m2 net on epibenthic sled, or 1.0-m2 Tucker trawl      Channel 1,545 1,544 957 1.0-m2 Tucker trawl      Bottom 1,389 1,388 928 1.0-m2 net on epibenthic sled          Fall Juvenile   Survey 5 JUL 5 DEC 11 Biweekly Shoal 427 427 3.0-m beam trawl, or 1.0-m2 Tucker trawl      Channel 648 648 1.0-m2 Tucker trawl      Bottom 1,055 1,055 3.0-m beam trawl          Beach Seine   Survey  14 JUN 24 OCT 10 Biweekly Shore 1,000 1,000  30.5-m beach seine  

__________  Table 2-3  Summary of 2010 Sample Collection Information by River Region and Stratum for the Longitudinal River          Ichthyoplankton Survey      3-Week Period from 15 MAR to 4 APR    3-Week Period from 5 APR to 25 APR    3-Week Period from 26 APR to 16 MAY        Shoal        Bottom Channel        Shoal        Bottom Channel      Shoal          Bottom Channel      Region      Sled Trawl    Sled    Trawl  Total Sled  Trawl  Sled    Trawl  Total Sled Trawl    Sled      Trawl  Total Battery -- -- 15 15 30 -- -- 24 18 42 -- -- 18 18 36 Yonkers 6 6 18 18 48 6 6 21 15 48 6 6 21 15 48 Tappan Zee 9 6 18 18 51 18 12 12 12 54 18 12 12 12 54 Croton-Haverstraw 9 6 18 18 51 12 9 12 12 45 12 9 12 12 45 Indian Point 6 6 18 18 48 6 6 12 12 36 6 6 18 30 60 West Point -- -- 15 15 30 -- -- 15 15 30 -- -- 18 45 63 Cornwall 6 6  12 12 36 9 6 9 9 33 9 6 24 15 54 Poughkeepsie -- -- -- -- -- -- -- 9 9 18 -- -- 30 30 60 Hyde Park -- -- -- -- -- -- -- 9 21 30 -- -- 27 33 60 Kingston -- -- -- -- -- -- -- 24 18 42 -- -- 18 21 39 Saugerties -- -- -- -- -- -- -- 24 18 42 -- -- 9 15 24 Catskill -- -- -- -- -- -- -- 48 21 69 -- -- 9 15 24 Albany -- -- -- -- -- -- -- 60 30 90 -- -- 15 15 30    Total 36 30 114 114 294 51 39 279 210 579 51 39 231 276 597    3-Week Period from 17 MAY to 6 JUN    4-Week Period from 7 JUN to 4 JUL      13-Week Period from 12 JUL to 10 OCT          Shoal        Bottom Channel        Shoal          Bottom Channel        Shoal            Bottom Channel      Region      Sled Trawl  Sled      Trawl  Total Sled  Trawl    Sled      Trawl  Total Sled  Trawl    Sled      Trawl  Total Battery -- -- 24 12 36 -- -- 24 16 40 -- -- 42 42 84 Yonkers 6 3 18 12 39 8 8 24 28 68 14 14 42 28  98 Tappan Zee 12 6 12 12 42 8 8 20 20 56 21 21 28 28  98 Croton-Haverstraw 12 6 12 12 42 12 8 24 24 68 21 21 28 28  98 Indian Point 6 6 18 36 66 12 8 20 64 104 21 21 28 28  98 West Point -- -- 21 45 66 -- -- 32  95 127 -- -- 28 28 56 Cornwall 9 6 24 15 54 7 8 49 48 112 14 14 20 21 69 Poughkeepsie -- -- 36 54 90 -- -- 28 60 88 -- -- 20 21 41 Hyde Park -- -- 21 30 51 -- -- 20 36 56 -- -- -- -- -- Kingston -- -- 12 18 30 -- -- 16 24 40 -- -- -- -- -- Saugerties -- -- 15 9 24 -- -- 16 8 24 -- -- -- -- -- Catskill -- -- 9 9 18 -- -- 12 12 24 -- -- -- -- -- Albany -- -- 9 9 18 -- -- 12 12 24 -- -- -- -- --    Total 45 27 231 273 576 47 40 297  447 831 91 91 236 224 642 __________ NOTE:  Dashes (--) indicate no sampling scheduled.

__________      Table 2-4  Specifications of Sampling Gear Used During the 2010 Longitudinal River                     Ichthyoplankton Survey                      1.0-m2 Tucker Trawl      Length  8.0 m  Mouth (width)  1.0 m  Mouth (height)  1.4 m  Mesh size  500 m  Net material  Nytex (monofilament nylon)      Collection cup      Length  30 cm    Length with net-retaining ring  37 cm    Mesh size  500 m    Net material  Nytex (monofilament nylon)        1.0-m2 Net Mounted on Epibenthic Sled      Length  8.0 m  Mouth (width)  1.0 m  Mouth (height)  1.4 m  Mesh size  500 m  Net material  Nytex (monofilament nylon)      Collection cup          Length  30 cm    Length with net-retaining ring  37 cm    Mesh size  500 m    Net material  Nytex (monofilament nylon)

__________  Table 2-5  Water Quality Sampling Locations During the 2010 Longitudinal River Ichthyoplankton and Fall Juvenile Surveys    Scheduled Sampling Locations (RM) Number of Water Quality Samples Scheduled Per Region Per River Run  River Region  Shoals1  Channel LRS  River Runs 1-3 LRS River Runs  4-16 LRS River Runs  17-23 FJS River Runs  1-11        Battery -- 1, 3, 6, 9 12 12 12 12        Yonkers 19 12, 14, 17, 19, 22 19 19 19 19        Tappan Zee 29 25, 27, 29, 32 16 16 16 16        Croton-Haverstraw 36 35, 36, 37, 38 16 16 16 16        Indian Point 43 40, 42, 43, 46 16 16 16 16        West Point -- 49, 51, 53, 55 12 12 12 12        Cornwall 59 56, 57, 59, 61 16 16 16 16        Poughkeepsie -- 63, 67, 71, 75 -- 12 12 12        Hyde Park -- 78, 80, 82, 84 -- 12 -- 12        Kingston -- 87, 89, 91, 93 -- 12 -- 12        Saugerties -- 96, 99, 102, 105 -- 12 -- 12        Catskill -- 109, 114, 118, 122 -- 12 -- 12        Albany -- 126, 131, 135, 138, 142 -- 15 -- 15          Total per River Run  107 182 119 182  __________ NOTE:  Dashes (--) indicate no sampling scheduled. 1 Sample collected from east and west shoals at designated river mile.

__________  Table 2-6  Summary of 2010 Sample Analysis Information by River Region and Stratum for the Longitudinal River          Ichthyoplankton Survey      3-Week Period from 15 MAR to 4 APR    3-Week Period from 5 APR to 25 APR      3-Week Period from 26 APR to 16 MAY        Shoal        Bottom Channel        Shoal          Bottom Channel      Shoal          Bottom Channel      Region      Sled Trawl  Sled      Trawl  Total Sled  Trawl    Sled      Trawl  Total Sled Trawl  Sled      Trawl  Total Battery -- -- 15 15 30 -- -- 12 9 21 -- -- 9 9 18 Yonkers 6 6 9 9 30 6 6 12 15 39 6 6 12 15 39 Tappan Zee 9 6 9 9 33 9 12 12 12 45 9 12 12 12 45 Croton-Haverstraw 9 6 9 9 33 12 9 12 12 45 12 9 12 12 45 Indian Point 6 6 9 9 30 6 6 12 12 36 6 6 9 15 36 West Point -- -- 15 15 30 -- -- 15 15 30 -- -- 9 9 18 Cornwall 6 6 12 12 36 9 6 9 9 33 9 6 12 15 42 Poughkeepsie -- -- -- -- -- -- -- 9 9 18 -- -- 15 15 30 Hyde Park -- -- -- -- -- -- -- 9 12 21 -- -- 15 18 33 Kingston -- -- -- -- -- -- -- 12 9 21 -- -- 9 12 21 Saugerties -- -- -- -- -- -- -- 12 9 21 -- -- 9 15 24 Catskill -- -- -- -- -- -- -- 9 12 21 -- -- 9 15 24 Albany -- -- -- -- -- -- -- 12 15 27 -- -- 15 15 30    Total 36 30 78 78 222 42 39 147 150 378 42 39 147 177 405      3-Week Period from 17 MAY to 6 JUN    4-Week Period from 7 JUN to 4 JUL              13-Week Period from 12 JUL to 10 OCT          Shoal        Bottom Channel        Shoal          Bottom Channel        Shoal            Bottom Channel      Region      Sled Trawl  Sled      Trawl  Total Sled  Trawl    Sled      Trawl  Total Sled  Trawl    Sled      Trawl  Total Battery -- -- 12 12 24 -- -- 12 16 28 -- -- 21 21 42 Yonkers 6 3 9 12 30 8 8 12 16 44 14 14 21 28 77 Tappan Zee 12 6 12 12 42 8 8 20 20 56 14 21 28 28 91 Croton-Haverstraw 12 6 12 12 42 12 8 12 12 44 21 21 28 28 98 Indian Point 6 6 9 18 39 12 8 20 12 52 14 21 28 28 91 West Point -- -- 12 9 21 -- -- 16 20 36 -- -- 28 28 56 Cornwall 9 6 12 15 42 7 8 25 24 64 14 14 20 21 69 Poughkeepsie -- -- 18 12 30 -- -- 16 12 28 -- -- 20 21 41 Hyde Park -- -- 12 15 27 -- -- 20 20 40 -- -- -- -- -- Kingston -- -- 12 9 21 -- -- 16 12 28 -- -- -- -- -- Saugerties -- -- 15 9 24 -- -- 16 8 24 -- -- -- -- -- Catskill -- -- 9 9 18 -- -- 12 12 24 -- -- -- -- -- Albany -- -- 9 9 18 -- -- 12 12 24 -- -- -- -- --    Total 45 27 153 153 378 47 40 209  196 492 77 91 194 203 565 __________ NOTE:  Dashes (--) indicate no sampling scheduled.

__________                      Table 2-7  Summary of 2010 Sample Collection by River Region and Stratum for the Fall Juvenile Survey            15-Week Period from 5 JUL to 17 OCT                  6-Week Period from 25 OCT to 5 DEC                  Shoal        Bottom  Channel          Shoal          Bottom  Channel        Region      Beam Tucker  Beam    Tucker Total Beam Tucker  Beam    Tucker Total  Battery -- 1 64 48 113 -- -- 35 -- 35  Yonkers 16 15 64 48 143 15 -- 34 -- 49  Tappan Zee 48 48 48 48 192 15 -- 24 -- 39  Croton-Haverstraw 40 40 48 48 176 15 -- 18 -- 33  Indian Point 32 32 56 55 175 15 -- 30 -- 45  West Point -- -- 80 98 178 -- -- 35 -- 35  Cornwall 40 40 48 48 176 15 -- 31 -- 46  Poughkeepsie -- -- 88 88 175 -- -- 30 -- 30  Hyde Park -- -- 64 48 112 -- -- 30 -- 30  Kingston -- -- 32 48 80 -- -- 24 -- 24  Saugerties -- -- 32 16 48 -- -- 30 -- 30  Catskill -- -- 24 24 48 -- -- 30 -- 30  Albany -- -- 32 31 64 -- -- 24 -- 24      Total 176 176 680 648 1680 75 -- 375 -- 450

__________  Table 2-8  Specifications of Sampling Gear Used During the 2010 Fall Juvenile Survey    1.0-m2 Tucker Trawl    Length 8.0 m  Mouth (width) 1.0 m  Mesh size 3.0 mm    Collection cage (codend)    Length 81 cm    Diameter 41 cm    Mesh size 3.0 mm      3.0-m Beam Trawl    Length 7.6 m  Beam width 3.0 m  Net body 3.8-cm mesh (stretch)  Codend 3.2-cm mesh (stretch) net with 1.3-cm mesh (stretch) liner  Hood 3.8-cm mesh (stretch)  Footrope Equipped with 5.1-cm rollers  Headrope Equipped with three floats  Mouth area 2.7 m2

__________  Table 2-9  Specifications of Sampling Gear Used During the 2010 Beach Seine Survey    30.5-m Beach Seine 

Number of wings 2  Length of wings 12.0 m  Depth of wings 2.4 m  Wing mesh (bar) 1.0 cm  Length of bag 6.1 m  Depth of bag 3.0 m  Bag mesh (bar) 0.5 cm  Sampling area 450 m2

__________      Table 2-11  Stratum and Region Volumes (m3) and Surface Areas (m2) Used in Analysis of 2010 Hudson River Estuary Data Geographic    Channel    Bottom      Shoal    Region  Shorezone        Region            Volume      Volume      Volume      Volume    Surface Area Battery 141,809,822 48,455,129 18,747,833 209,012,784 (a)      Yonkers 143,452,543 59,312,978 26,654,767 229,420,288 3,389,000  Tappan Zee 138,000,768 62,125,705 121,684,992 321,811,465 20,446,000  Croton-Haverstraw 61,309,016 32,517,633 53,910,105 147,736,754 12,101,000 Indian Point 162,269,471 33,418,632 12,648,163 208,336,266 4,147,000  West Point 178,830,022 25,977,862 2,647,885 207,455,769 1,186,000  Cornwall 94,882,267 36,768,629 8,140,123 139,791,019 4,793,000  Poughkeepsie 228,975,052 63,168,132 5,990,260 298,133,444 3,193,000 Hyde Park 131,165,041 32,012,000 2,307,625 165,484,666 558,000  Kingston 93,657,021 35,479,990 12,332,868 141,469,879 3,874,000  Saugerties 113,143,296 42,845,077 20,307,338 176,295,711 7,900,000  Catskill 83,924,081 42,281,206 34,526,456 160,731,743 8,854,000  Albany    32,025,080  13,517,183  25,606,842    71,149,105  6,114,000      Total 1,603,443,480 527,880,156 345,505,257 2,476,828,893 76,555,000    ___________  a. Shorezone surface area is unknown and not used in data analysis as no beach seine sampling is performed in the    Battery region.  

__________    This chapter provides graphs on the parameters of temperature, salinity, and dissolved oxygen as measured during the 2010 surveys. In addition, freshwater flow data obtained from the U.S. Geological Survey (USGS) for the Green Island Dam near Troy, New York, and daily water temperature data from Poughkeepsie and the near-by USGS gaging site are also graphed. Supporting tables are presented in Appendix B. During 2010, daily freshwater flow for Green Island, New York was estimated from discharge data provided by the USGS for the Hudson River above Lock 1, the Mohawk River at Cohoes, and the Mohawk River diversion at Crescent Dam. At the time of publication, the data from October through December 2010 were incomplete and provisional. Links to Graphs Figure Supporting Appendix Table Daily freshwater flow rates for 2010 3-1 B-1 Monthly freshwater flow rates for 2010 3-1 B-2 Monthly average freshwater flow rates for 1974 to 2010 3-1 B-3 Average annual freshwater flow for 1947 to 2010 3-2 B-4    Long-term (since 1951) daily temperature records are available from PoughkeepsieTreatment Facility, located just north of the City of Poughkeepsie, New York, at RM 77. In addition, water temperature records dating back to 1993 are available from the USGS gaging site (#01372058) on the Hudson River 2.3 miles below Poughkeepsie, New York, at RM 72. Because of the consistency and verification of the USGS records, they were substituted for the Water Treatment Facility records beginning with 1993 and continuing to 2010. Temperature records from the Water Treatment Facility were retained for 1951 through 1992.

Links to Graphs Figure Supporting Appendix Table Daily water temperatures for 2010 3-3 B-5 Average, minimum, and maximum temperatures for 1951 to 2009 3-3 B-5 Average annual water temperature for 1951 to 2010 3-4 B-6  measurements of water temperature (&deg;C), dissolved oxygen (mg/L), and specific conductance (microsieman/cm at 25&deg;C) were taken with calibrated meters at fixed river mile and strata stations in conjunction with biological sampling for the LRS and FJS. These three parameters were also measured with each sample of the BSS. Salinity data were computed from conductivity data as detailed in Chapter 2.

__________  Links to Graphs Figure Supporting Appendix Table Weekly temperatures for LRS/FJS for 2010 3-5 B-7 Weekly average, minimum, and maximum temperatures for LRS/FJS for 1974 to 2009 3-5 --- Average annual temperature for LRS/FJS for 1974 to 2010 3-5 B-8 Weekly temperatures for BSS for 2010 3-6 B-9 Weekly average, minimum, and maximum temperatures for BSS for 1974 to 2009 3-6 --- Average annual temperature for BSS for 1974 to 2010 3-6 B-10 Average weekly salinity for LRS/FJS for 2010 3-7 B-11 Weekly dissolved oxygen for LRS/FJS for 2010 3-8 B-13 Weekly average, minimum, and maximum dissolved oxygen for LRS/FJS for 1974 to 2009 3-8 ---Average annual dissolved oxygen for LRS/FJS for 1974 to 2010 3-8 B-14 Weekly dissolved oxygen for BSS for 2010 3-9 B-15 Weekly average, minimum, and maximum dissolved oxygen for BSS for 1974 to 2009 3-9 ---Average annual dissolved oxygen for BSS for 1974 to 2010 3-9 B-16 

EA Engineering, Science, and Technology. 1991. 1989 Year Class Report for the Hudson River estuary monitoring program. Prepared for Consolidated Edison Company of New York, Inc. EA Engineering, Science, and Technology. 1996. 1995 Year Class Report for the Hudson River estuary monitoring program. Prepared for Consolidated Edison Company of New York, Inc. Lawler, Matusky & Skelly Engineers (LMS). 1989. 1986 and 1987 Year Class Report for the Hudson River estuary monitoring program. Prepared for Consolidated Edison Company of New York, Inc.

Lawler, Matusky & Skelly Engineers. 1992. 1990 Year Class Report for the Hudson River estuary monitoring program. Prepared for Consolidated Edison Company of New York, Inc.

Lawler, Matusky & Skelly Engineers. 1996. 1991 Year Class Report for the Hudson River estuary monitoring program. Prepared for Consolidated Edison Company of New York, Inc.

Nelson, J.S., E.J. Crossman, H. Espinosa-P&#xe9;rez, L.T. Findley, C.R. Gilbert, R.N. Lea, and J.D. Williams. 2004. Common and scientific names of fishes from the United States, Canada, and Mexico. American Fisheries Society, Special Publication 29, Bethesda, Maryland.

Normandeau Associates, Inc. 1985b. 1983 Year Class Report for the Hudson River estuary monitoring program. Prepared for Consolidated Edison Company of New York, Inc. Texas Instruments, Inc. (TI). 1975. First annual report for the multiplant impact study of the Hudson River estuary. Prepared for Consolidated Edison Company of New York, Inc.

Texas Instruments, Inc. 1977. 1974 Year Class Report for the multiplant impact study of the Hudson River estuary. Prepared for Consolidated Edison Company of New York, Inc.

Texas Instruments, Inc. 1978. 1975 Year Class Report for the multiplant impact study of the Hudson River Estuary. Prepared for Consolidated Edison Company of New York, Inc.

Texas Instruments, Inc. 1979. 1976 Year Class Report for the multiplant impact study of the Hudson River estuary. Prepared for Consolidated Edison Company of New York, Inc.

Texas Instruments, Inc. 1980a. 1977 Year Class Report for the multiplant impact study of the Hudson River estuary. Prepared for Consolidated Edison Company of New York, Inc.

Texas Instruments, Inc. 1980b. 1978 Year Class Report for the multiplant impact study of the Hudson River estuary. Prepared for Consolidated Edison Company of New York, Inc.

Texas Instruments, Inc. 1981. 1979 Year Class Report for the multiplant impact study of the Hudson River estuary. Prepared for Consolidated Edison Company of New York, Inc.

Versar, Inc. 1987. 1985 Year Class Report for the Hudson River estuary monitoring program. Prepared for Consolidated Edison Company of New York, Inc.  

Table B-2  Long-Term (1947-2009) and 2010 Monthly Mean Freshwater Flow (m3/sec/day) Estimated for Green Island, New York                  2010    LONG-TERM  LONG-TERM  LONG-TERM MONTH        AVERAGE    AVERAGE    MINIMUM    MAXIMUM  JAN            236        409        118        961 FEB            226        402        128        885 MAR            454        627        258      1,077 APR            349        872        257      1,749 MAY            142        524        156      1,147 JUN            139        301        101        909 JUL            121        201        87        670 AUG            118        174        48        414 SEP            101        183        58        482 OCT1            159        262        71        853 NOV1            211        379        93        758 DEC1            337        432        173        989 ANNUAL AVERAGE2        216        397

Table B-5 (Continued)                              LONG-TERM    TEMPERATURE    (1951-2009)              2010 ACTUAL MONTH    DAY             MEAN              MINIMUM              MAXIMUM          TEMPERATURES    8      7            25.4              23.3                28.0                27.2    8      8            25.4              23.3                28.0                27.2    8      9            25.5              23.3                28.0                27.2    8      10            25.5              23.3                28.0                27.3    8      11            25.4              22.8                28.0                27.4 8      12            25.4              22.8                28.1                27.4    8      13            25.3              22.2                28.5                27.3    8      14            25.3              22.2                28.5                27.2    8      15            25.2              22.2                28.4                26.9    8      16            25.2              22.2                28.4                26.8    8      17            25.1              22.2                28.1                26.8    8      18            25.1              22.8                28.0                26.8    8      19            25.1              22.2                27.7                26.8    8      20            25.1              22.8                27.6                26.8    8      21            25.0              22.2                27.5                26.6    8      22            24.9              22.2                27.5                26.5    8      23            24.8              22.8                27.0                26.1    8      24            24.8              22.2                27.0                25.4    8      25            24.7              21.7                27.0                24.9    8      26            24.7              21.7                27.0                24.8    8      27            24.7              22.2                26.5                24.5    8      28            24.6              22.2                26.5                24.4 8      29            24.5              22.2                26.7                24.4    8      30            24.5              22.2                26.5                24.5    8      31            24.4              22.2                26.5                24.6    9      1            24.3              22.2                26.5                24.8    9      2            24.2              22.2                26.7                24.9 9      3            24.1              22.2                26.1                25.0    9      4            24.1              22.2                26.0                25.0    9      5            24.0              21.7                26.0                24.5    9      6            24.0              22.0                26.0                24.4    9      7            23.8              21.7                26.0                24.5    9      8            23.7              21.7                26.0                24.6    9      9            23.6              21.7                25.6                24.2    9      10            23.5              21.1                25.6                23.9    9      11            23.4              21.1                25.6                23.8    9      12            23.3              21.1                25.6                23.7    9      13            23.1              20.0                25.6                23.6    9      14            23.0              18.9                25.5                23.5    9      15            22.8              17.8                25.5                23.3    9      16            22.6              17.2                25.5                23.1    9      17            22.4              17.2                25.5                23.0    9      18            22.2              16.7                25.5                22.9    9      19            22.1              16.7                25.5                22.8 9      20            22.0              17.2                25.5                22.5    9      21            21.7              16.7                25.0                22.4    9      22            21.5              16.1                25.0                22.3 9      23            21.2              16.1                25.0                22.3    9      24            21.1              15.6                24.5                22.4    9      25            20.9              15.6                24.5                22.5    9      26            20.8              15.6                24.0                22.2    9      27            20.6              16.1                24.0                22.1    9      28            20.4              15.6                23.5                22.1    9      29            20.2              15.6                23.5                22.0    9      30            20.0              15.6                23.0                21.9 10      1            19.8              16.1                22.7                21.3  10      2            19.6              15.6                22.5                20.3  10      3            19.5              15.6                22.6                19.5  10      4            19.2              15.6                22.7                18.8  10      5            19.0              15.0                22.7                18.1  10      6            18.8              15.0                22.7                17.8  10      7            18.7              15.0                22.6                17.4  10      8            18.4              14.4                22.6                16.7  10      9            18.1              14.4                22.4                16.3  10      10            18.0              14.4                22.2                15.9  10      11            17.8              13.9                22.0                15.8  10      12            17.6              13.3                21.5                15.7  10      13            17.3              13.3                21.1                15.5  10      14            17.1              12.8                21.1                15.2  10      15            16.9              12.2                20.5                15.0  10      16            16.7              12.2                20.3                14.5  10      17            16.5              12.8                20.2                14.4 10      18            16.3              12.2                20.2                14.2 Table B-5 (Continued)                              LONG-TERM    TEMPERATURE    (1951-2009)              2010 ACTUAL MONTH    DAY            MEAN              MINIMUM              MAXIMUM          TEMPERATURES    10      19            16.0              11.7                20.2                14.1  10      20            15.8              10.6                20.0                14.0  10      21            15.4              10.6                19.7                13.8  10      22            15.1              10.0                19.6                13.4 10      23            14.9              10.0                19.6                13.1  10      24            14.7              10.0                19.3                13.1  10      25            14.6              10.0                19.0                13.2  10      26            14.3              10.0                18.6                13.4  10      27            13.9                9.4                18.2                13.4  10      28            13.8                8.9                17.8                13.0  10      29            13.5                8.3                17.8                12.5  10      30            13.2                7.8                16.7                12.2  10      31            13.1                7.2                16.7                11.9  11      1            12.8                7.2                16.7                11.6  11      2            12.6                7.2                16.1                11.4  11      3            12.4                7.2                16.1                11.3  11      4            12.2                7.2                15.6                11.1  11      5            12.0                7.2                15.6                11.0  11      6            11.7                6.7                15.6                10.6  11      7            11.5                6.1                15.0                10.1  11      8            11.3                6.1                15.0                  9.7 11      9            11.1                5.6                15.0                  9.4  11      10            10.8                5.0                14.4                  9.3  11      11            10.5                5.0                13.9                  9.1 11      12            10.3                5.0                13.3                  8.9  11      13            10.1                5.0                13.3                  8.6  11      14            9.9                5.0                13.3                  8.4  11      15            9.8                5.0                12.8                  8.3  11      16            9.5                5.0                12.8                  8.1 11      17            9.2                5.0                12.8                  8.1  11      18            9.1                5.0                12.8                  7.6  11      19            8.9                5.0                12.2                  7.4  11      20            8.6                5.0                11.1                  7.2  11      21            8.4                3.9                11.1                  7.1  11      22            8.2                3.9                11.1                  7.2  11      23            8.0                3.9                11.1                  7.2  11      24            7.7                3.9                10.6                  6.9  11      25            7.4                3.9                10.6                  6.7  11      26            7.2                3.3                10.5                  6.8  11      27            7.0                3.3                10.5                  6.5  11      28            6.9                3.3                10.5                  6.4  11      29            6.7                3.3                10.5                  6.3  11      30            6.5                2.8                10.5                  6.3  12      1            6.2                2.2                10.5                  6.6  12      2            6.0                3.0                10.0                  6.0  12      3            5.7                2.2                  9.5                  5.4 12      4            5.5                1.3                  9.5                  5.2  12      5            5.3                2.8                  9.5                  5.0  12      6            5.2                2.6                  9.5                  4.7 12      7            5.1                2.0                  9.5                  4.3  12      8            4.8                2.0                  9.0                  3.9  12      9            4.5                1.7                  9.0                  3.6  12      10            4.3                1.1                  9.0                  3.4  12      11            4.1                1.1                  8.5                  3.4  12      12            3.9                0.6                  8.5                  3.5  12      13            3.7                0.6                  8.5                  3.3  12      14            3.5                0.5                  8.5                  2.1  12      15            3.3                0.5                  8.5                  1.6  12      16            3.2                0.5                  8.0                  1.3  12      17            3.0                0.0                  8.0                  1.1  12      18            2.8                0.0                  7.5                  1.0  12      19            2.6                0.0                  7.5                  0.8  12      20            2.6                0.0                  7.5                  0.4  12      21            2.4                0.0                  7.0                  0.2  12      22            2.2                0.0                  6.5                  0.1  12      23            2.1                0.0                  6.5                -0.1  12      24            2.0                0.0                  6.5                -0.1  12      25            1.9                0.0                  6.0                -0.1  12      26            1.7                0.0                  6.1                -0.2  12      27            1.7                0.0                  6.1                -0.1  12      28            1.7                0.0                  6.1                -0.1  12      29            1.6                0.0                  6.1                -0.1  12      30            1.6                0.0                  6.1                -0.1  12      31            1.5                0.0                  5.0                -0.1 Table B-6  Average Annual Water Temperature (&deg;C), Hudson River near Poughkeepsie, 1951 to 20101  YEAR TEMPERATURE YEAR TEMPERATURE 1951 11.66 1981 12.63 1952 12.25 1982 12.48 1953 12.87 1983 13.01 1954 11.92 1984 13.04 1955 12.40 1985 13.05 1956 11.92 1986 12.69 1957 13.03 1987 12.66 1958 12.18 1988 12.57 1959 12.90 1989 12.09 1960 11.29 1990 12.77 1961 12.17 1991 13.67 1962 11.63 1992 12.10 1963 11.82 1993 12.09 1964 12.99 1994 12.24 1965 12.51 1995 12.47 1966 12.75 1996 11.83 1967 12.05 1997 12.07 1968 13.10 1998 13.66 1969 12.59 1999 13.08 1970 12.79 2000 12.00 1971 12.31 2001 13.24 1972 11.35 2002 12.85 1973 12.73 2003 11.80 1974 11.61 2004 12.37 1975 12.37 2005 12.68 1976 11.43 2006 12.77 1977 11.97 2007 12.97 1978 12.27 2008 12.54 1979 12.49 2009 12.30 1980 12.72 2010 13.10  1 Data from 1951 through 1992 from PoughkeepsFacility. Data from 1993 through 2010 from USGS gaging site 01372058 Hudson River below Poughkeepsie, NY. 

Table B-7  Weighted Mean Temperature (&deg;C) by Region and Week from 2010 Long River/Fall Juvenile Survey WEEK                                                    REGIONS BEGINNING MONDAY      BT      YK      TZ      CH      IP      WP      CW      PK      HP      KG      SG      CS      AL 15MAR10    4.9    5.0    5.2    5.4    5.6    5.3    4.9      .      .      .      .      .      . 22MAR10    6.7    7.0    6.9    6.8    6.9    7.1     6.9      .      .      .      .      .      .

14JUN10    23.2    22.6    22.2  23.9    21.7    22.7    22.9    23.4    22.3    21.9    21.3    20.7 28JUN10    27.4    27.0    26.8  27.1   24.1    23.7    24.6    25.3    25.6    25.2    26.1    25.6 12JUL10    25.1    26.8    27.0  25.0    26.4    28.1    27.2    27.8    27.2    27.1    27.2    27.5 26JUL10    27.9    27.3    29.5  28.9    28.2    28.5    28.2    27.4    26.7    27.3    28.0    26.8 09AUG10    26.5    26.9    27.4  28.1    27.3    27.1    26.8    26.9    26.5    26.0    27.8    27.0 23AUG10    24.5    24.6    25.0  23.6    25.3    25.3    24.8    24.0    23.2    23.4    23.2    21.7 06SEP10    24.9    23.5    24.3  24.6    25.0    24.0    23.9    23.5    23.3    24.0    24.3    23.8 20SEP10    20.9    21.0    20.9  23.6    22.4    22.0    21.7    20.4    19.3    20.5    19.8    18.5 04OCT10    16.9    16.5    16.8  17.0    16.4    15.3    15.3    14.0    13.3    12.9    12.6    12.3 18OCT10    10.6    10.2    10.6  11.8    10.1    9.0    9.0    8.2    8.6    8.3    7.1    6.2 

Table B-10 Average Annual Temperature (&deg;C) from Beach Seine Surveys, 1974 to 2010  YEAR TEMPERATURE 1974 21.34 1975 21.59 1976 22.21 1977 22.85 1978 23.71 1979 23.05 1980 24.29 1981 21.91 1982 22.73 1983 24.53 1984 23.17 1985 23.38 1986 22.02 1987 23.03 1988 23.16 1989 24.15 1990 24.34 1991 23.63 1992 22.07 1993 23.48 1994 22.39 1995 23.85 1996 24.42 1997 22.41 1998 24.20 1999 23.42 2000 22.32 2001 24.89 2002 24.52 2003 23.69 2004 22.60 2005 25.69 2006 23.27 2007 23.74 2008 23.85 2009 23.88 2010 23.06 Table B-11  Weighted Mean Salinity (ppt) by Region and Week from 2010 Long River/Fall Juvenile Survey WEEK                                                    REGIONS BEGINNING MONDAY      BT      YK      TZ      CH      IP      WP      CW      PK      HP      KG      SG      CS      AL 15MAR10    11.3    5.0     3.2     1.7    0.2    0.1     0.1     .      .      .      .      .      . 22MAR10    6.6    0.7    0.1     0.1     0.1    0.1    0.1      .      .      .      .      .      . 29MAR10    6.5     0.9     0.1    0.1    0.1    0.1    0.1     .       .       .       .       .      . 05APR10    6.8    1.1    0.1    0.1    0.1     0.1    0.1    0.1    0.1     0.1    0.1    0.1     0.1 12APR10    16.7    12.2    4.9    2.1     0.6    0.1    0.1     0.1     0.1    0.1    0.1    0.1     0.1 19APR10    11.3    6.7    4.2    1.8    0.5     0.1    0.1     0.1     0.1    0.1    0.1     0.1     0.1 26APR10    14.5     9.0     2.8    0.5    0.1    0.1    0.1     0.1    0.1    0.1     0.1    0.1    0.1 03MAY10    12.6    7.0     3.4     1.5    0.4    0.1    0.1     0.1     0.1     0.1    0.1    0.1    0.1 10MAY10    17.8    12.2     7.7    5.1     2.9     1.2     0.3    0.1     0.1    0.1    0.1    0.1    0.1 17MAY10    15.9   11.1    7.2     4.8    3.0     0.6    0.1    0.1    0.1     0.1    0.1    0.1    0.1 24MAY10    19.2    12.5    9.1    5.6    3.7     0.9    0.3     0.1     0.1    0.1    0.1    0.1     0.1 31MAY10    17.8   11.3     6.7    4.2    3.0     1.0    0.2     0.1     0.1    0.1    0.1    0.1     0.1 07JUN10    20.7    15.4    10.5     7.3    4.8     2.6    1.5     0.2     0.1    0.1    0.1    0.1    0.1 14JUN10    15.5    9.3     6.0     3.8    2.8    1.2     0.2     0.1    0.1    0.1    0.1    0.1    0.1 21JUN10    22.1    16.3    9.3    5.1    3.1    0.8     0.4    0.1    0.1    0.1    0.1    0.1    0.1 28JUN10    16.6    9.8    6.1    3.9    2.5     0.7    0.2     0.2    0.2    0.2    0.2     0.1    0.1 05JUL10    22.4    17.7    11.8     7.5    6.2    3.0     1.6    0.2     0.1    0.2     0.1    0.1    0.1 12JUL10    18.6    13.4    9.6    7.2     6.5     5.0     1.6    0.2     .       .      .       .       . 19JUL10    22.2   16.2   10.3    6.5    4.3    2.4    1.7    0.4    0.1    0.1    0.1    0.1    0.1 26JUL10    19.5    14.0     9.3    6.2     4.9    2.1    0.6    0.2     .       .       .       .       . 02AUG10    24.2    16.8    9.8    6.3    4.1    1.8    0.7    0.2     0.1    0.1    0.1     0.1    0.1 09AUG10    22.4    17.4    10.3     7.0     5.6    2.9    1.0     0.1      .       .      .       .       . 16AUG10    22.6    17.0   10.9    6.6    4.3    2.2    1.3     0.3    0.1    0.1     0.1    0.1     0.1 23AUG10    17.8    13.2     9.2    5.9    4.2     1.2    0.2    0.1     .       .       .       .       . 30AUG10    19.2   12.8    7.6    4.0     2.1    0.3     0.1     0.1     0.1    0.1     0.1     0.1    0.1 06SEP10    19.2    15.0    8.2    5.4     4.4    1.8    0.4     0.1     .       .      .      .      . 13SEP10    20.7    12.4     8.5     5.3     3.0     1.2    0.6    0.2     0.1    0.1     0.1    0.1    0.1 20SEP10    22.2   16.2    10.9    8.1    6.0     3.8    1.3    0.1     .       .      .      .      . 27SEP10    20.8    13.2     9.1    6.7    5.3     2.7    1.4    0.4     0.1    0.1    0.1    0.1    0.1 04OCT10    16.0    7.3     4.0     1.0     0.2     0.1    0.1    0.1      .      .       .       .      . 11OCT10    15.9    6.3     1.6    0.1    0.1    0.1    0.1    0.1    0.1    0.1    0.1     0.1    0.1 25OCT10    18.2    13.2    5.4    1.7    0.8    0.1    0.1    0.1     0.1    0.1    0.1     0.1     0.1 08NOV10    13.4    9.4    7.0    2.3     0.6    0.1     0.1     0.1    0.1     0.1     0.1    0.1    0.1 29NOV10    13.4     5.8     2.2     0.4     0.1    0.1    0.1    0.1    0.1    0.1    0.1    0.1    0.1