{{#Wiki_filter:IMPINGEMENT OF ORGANISMS ON THE INTAKE SCREENS AT PILGRIM NUCLEAR POWER STATION JANUARY -DECEMBER 2010 Submitted to Entergy Nuclear Pilgrim Nuclear Power Station Plymouth, Massachusetts by Normandeau Associates, Inc.Falmouth, Massachusetts NORMANDEAU ASSOCIATES , ENVIRONMENTAL CONSULTANTS April 22, 2011 V ~j)

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Introduction Pilgrim Nuclear Power Station (PNPS) is located on the northwestern shore of Cape Cod Bay (Figure 1) with a licensed capacity of 685 megawatts.

The unit has two circulating water pumps with a capacity of approximately 345 cfs (155,500 gallons per minute) each and five service water pumps (2,500 gallons per minute each) with a combined capacity of 23 cfs. Water is drawn under a skimmer wall, through vertical bar racks spaced approximately three inches on center, and finally through vertical traveling screens of /2 x 1/4 inch mesh (Figure 2). There are four vertical screens, two for each circulating water pump.This report describes the monitoring of impinged organisms at Pilgrim Station based on screen wash samples taken from January to December 2010 and provides documentation of the environmental monitoring and reporting requirements of NPDES Permit No. MA0003557 (USEPA) and No. 359 (MA DEP).Methods and Materials Three scheduled screen wash periods were monitored each week from January to December 2010. These included the 0830 wash on Monday, the 1630 wash on Wednesday, and the 0030 wash on Saturday.

Each sampling period thus represented a separate, distinct eight-hour period. Prior to each sampling period, the time of the previous screen wash was obtained from a strip chart recorder located in the screen house or from the Control Room log to permit the actual sampling interval to be calculated.

Whenever the screens were static upon arrival a 30-minute sample was collected, and if the screens were already operating then a 60-minute sample was obtained.Low and high pressure spray nozzles directed at the screens washed impinged organisms and debris into a sluiceway which was sampled by inserting a collection basket made of stainless steel mesh. All fauna were identified and noted as being alive, dead, or injured. Fish were determined to be alive if they showed opercular movement and no obvious signs of injury.Fauna determined to be alive were measured for total length (mm), then released.

Those determined to be dead or injured were preserved.

In the lab, the weights (grams) and total lengths (mm) were recorded for up to 20 specimens of each species. The impingement rate was calculated by dividing the number of fish collected by the number of hours in the collection period. Counts made from all collections during a month were pooled and then extrapolated to estimate a monthly total (total number of fish in each month divided by the total collection hours in each month) x 24 hours x number of days in the month. These monthly totals were summed to derive an annual total adjusted for number of collection hours.If an impingement rate of 20 fish per hour was obtained for static washes, an additional one-hour sample was taken. If at least 20 fish were present in the extra 60-minute collection period the Operator and Shift Manager were immediately informed and advised to leave the screens operating until further notice. Additional follow-up sampling would be performed at approximately 4-hour intervals, as warranted by conditions until the impingement rate declined to less than 20 fish per hour. As these subsequent samples were taken communication typically 2 Normandeau Associates, Inc.

z 0 r"i a 42B SA WAL IN KM Plymouth 0 Nuclear. Cape Cod B&y rn Powmr E, tstaiom ~Figure 1. Location of Pilgrim Nuclear Power Station N"go z 0710 td,SAs " jh El-- -- -- -- IllK*RAW Li IEVEL RM)1L Ormac CD,~Figure 2. Cross-section of intake structure of Pilgrim Nuclear Power Station.0.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring occurred in order to keep all appropriate individuals updated. A similar procedure was followed if 20 or more fish were found in an initial continuous wash sample, with additional monitoring occurring until the impingement rate was less than 20 fish per hour. As in the case of static wash samples all appropriate individuals were kept apprised as conditions changed.Results and Discussion Fish In 434.78 collection hours, an estimated total of 32,962 fish consisting of 33 species was collected during sampling completed from January -December 2010 (Table 1, Figure 3).Atlantic silversides (Menidia menidia), alewife (Alosapseudoharengus), Atlantic menhaden, (Brevoortia tyrannus), winter flounder (Pseudopleuronectes americanus), rainbow smelt (Osmerus mordax), and cunner (Tautogolabrus adspersus), were the top six numerical dominants accounting for 41, 38, 4, 3, 3 and 2 %, respectively, of the annual total. The overall impingement rate of all fish combined in 2010 was 4.43 fish per hour, ranging from 16.7 in July down to 0.1 fish per hour in June (Table 1).Atlantic silversides, historically one of the most numerous fish impinged at PNPS, ranked first with an estimated annual total of 13,576 fish. Silversides were represented in the catch every month but were most abundant in April (8,233 fish), when 61% of the annual total was collected (Table 1). Impinged silversides were all young-of-the-year and age 1 fish (see Conover and Murawski 1982) ranging in size from 63 to 152 mm with a mean length of 95 mm (Table 2).Alewife ranked second in 2010 with an extrapolated total of 12,680 fish. They were impinged most often in July when 95% of the annual total was obtained (Table 1). The remaining individuals were found in March, April, May, August, and October through December.

Impinged alewives were juvenile fish ranging in size from 64 to 172 mm with a mean length of 95 mm (Table 2).Menhaden were impinged from July through December with 65% of the year's total being collected in August. Winter flounder were impinged every month except for June, September, and October; 63% were recorded from January through March. Smelt were most common in November, and March, 68% of the fish being impinged during those two months.Lastly, cunner were represented in the catch primarily during the cold months of November through February; 93% of the fish were taken during those months.In 2010 there were two brief impingement incidents where the sampled impingement rate exceeded 20 fish per hour; one in April and one in July. The April sample, taken on the 1 2 th, involved Atlantic silversides and spotted hake impinged at the rate of 25 fish per hour. The July sample, taken onthe 28th , contained five species impinged at a combined rate of 236 fish per hour. Silversides accounted for 99.5% of the April catch and alewives accounted for 99.4% of the July catch. In both cases subsequent samples taken immediately following the first (3 and 0 fish per hour, respectively) indicated that the relatively high rates of impingement were of short duration.5 NormandeauAssociates, Inc, Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Station Impingement January -December 2010 Atlantic Silverside 41.2%unner 1.6%Rainbow Smelt 2.8%Winter Flounder 3.1%Atlantic Menhaden 4.3%27 Remaining Species 8.7%Alewife 38.5 Figure 3. Percent of total for numerically dominant species of fish impinged on the Pilgrim Nuclear Power Station intake screens, January to December 2010.Annual extrapolated totals for all species impinged from 1980 to 2010 along with their respective 1980 to 2009 long-term means are shown in Table 3; results for the 14 typical dominants and total fish are also shown in Figure 4. The select 14 species typically account for greater than 90% of the annual total collected on the screens. The 2010 impingement total of 32,962 fish was 71% of the 30-year mean of 46,516 fish impinged.

The below average value in 2010 was clearly due to reduced numbers of Atlantic menhaden which have typically ranked first or second over the 1980 to 2009 time period; in 2010 their annual total (1,403) amounted to only 5% of the time series mean of 25,691 fish. Overall among the remaining numerical dominants silversides, alewife, cunner, and lumpfish were above average in number in 2010. The alewife total, in particular, was seven times the time series mean. Grubby, smelt, tomcod, hakes, blueback herring, windowpane, tautog, and Atlantic herring were below average in number.Winter flounder numbers were near average (1005 in 2010 compared with a mean of 975).6 Normandeau Associates, Inc.6 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Previous large impingement events, defined as those involving more than 1,000 fish, are documented in Table 4. The short-lived influx of alewives in July represented the only such event in 2010 and the first one occurring since September 2007. At PNPS menhaden and silversides have accounted for 15 of the 21 cases. These events often occur in the late summer and autumn when young fish are abundant, actively moving offshore for the winter and water temperatures are declining.

As water temperatures drop, metabolism declines along with swimming ability.Impingement rates (number of fish collected divided by number of collection hours) for each species and their respective estimated annual totals for 2010 are presented in Table 5.Alewife and silverside yielded the highest impingement rates (2.465 and 1.290 fish/hour, respectively).

For all species combined, the impingement rates were 4.44 fish/hour and 32,962 fish/year, ranking 11th over the 31-year time series from 1980 to 2010 (Table 6). The average annual impingement total recorded from 1980 to 2009 was 46,448 fish per year, ranging from 1,112 (1984) to 302,883 (2005) fish per year.Since 1980, 80 species of fish have been collected on the PNPS intake screens (Table 7).Nine species of fish (alewife, Atlantic silverside, Atlantic tomcod, blueback herring, cunner, grubby, hakes, rainbow smelt, and winter flounder) were collected every year from 1980 to 2010.Eight other species, Atlantic herring, Atlantic menhaden, lumpfish, northern pipefish, rock gunnel, tautog, threespine stickleback, and windowpane were present at least 90% of the time (>28 annual occurrences).

Invertebrates From January to December 2010, 12,454 invertebrates representing 13 taxa (Table 8)were estimated to have been impinged at Pilgrim Station yielding an impingement rate of 1.4 invertebrates per hour. Sevenspine bay shrimp (Crangon septemspinosa) ranked first and accounted for 51% of the annual estimated total. They were primarily impinged in January, February and April when 28, 35 and 24%, respectively, of the 6,368 estimated total was collected.

Cancer crabs (Cancer spp) and green crabs (Carcinus maenas) ranked second and third in numerical order accounting for 18 and 8%, respectively, of the annual invertebrate total.Cancer crabs were present throughout the year and were most abundant in November when 22%of their total (2,301 crabs) was collected.

Green crabs were also impinged every month and were most abundant in January when 28% of their annual total of 999 crabs was impinged.

Seventeen American lobsters (Homarus americanus) were impinged during sampling periods in 2010 ranging in size from 12 to 143mm, yielding an annual estimated total of 350 animals. Among the seventeen lobsters collected three were of legal size (> 82 mm) and the rest were less that 80 mm and likely juveniles.

Table 9 presents annual estimated totals for impinged invertebrates dating back to 1980.Based on the times series mean the bay shrimp total for 2010 was below average amounting to 89% of the mean. The green crab total was also below average amounting to 75% of the mean.In contrast, rock crab were impinged in above average numbers, 1.6 times the mean (2301 compared with 1447)..7 Normandeau Associates, hic.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement.

: 1. The average hourly impingement rate for 2010 at Pilgrim Station from January to December was 4.4 fish per hour for all fish combined.

The estimated annual impingement total of 32,962 fish ranked I Ith over the 31-year time series, 66% of all previous annual totals were lower.2. Thirty-three species of fish were sampled in 437.28 collection hours in 2010.3. Atlantic silversides, alewife, Atlantic menhaden,, winter flounder, rainbow smelt, and cunner, were the numerical dominants accounting for 41, 38, 4, 3, 3 and 2 %, respectively, of the annual total.4. In 2010 there were two brief impingement incidents where the sampled impingement rate exceeded 20 fish per hour; one in April and one in July.Silversides accounted for 99.5% of the April catch and alewives accounted for 99.4% of the July catch. In both cases subsequent samples indicated that the relatively high rates of impingement were of short duration.5. The short-lived influx of alewives in July represented the only large impingement event (more than 1,000 fish) in 2010 and the first one that occurred since September 2007.6. Invertebrates were impinged at a rate of 1.4 animals per hour. Sevenspine bay shrimp, cancer crabs and green crabs accounted for 51, 18, and 8% of the 2010 estimated annual total of 12,454 invertebrates.

S Norrnandeau Associates, Inc.8 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Literature Cited Conover, D.O. and S.A. Murawski.

1982. Offshore winter migration of the Atlantic silverside, Menidia menidia. Fishery Bulletin U.S. 80(1):145-150.

Witherell, D.B. and J. Burnett. 1993. Growth and maturation of winter flounder, Pleuronectes americanus, in Massachusetts.

9 Normandeau Associates, Inc.9 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Atlantic Silverside Pilgrim Nuclear Power Station Impingement Extrapolated Total 10 0 ,00 0 -:- -. .--. ."" 13 25 .7 29 91 93 95 97 99 '01 03 01 07 .09 0 .TtA. -Mean 980-2 Atlantic Menhaden Pilgrim Nuclear Power Station Impingement Extrapolated Tota 1,00,000 --- ----------100,000 10,000 100 10-10 22 84 86 82 90 92 94 96 92 '00 N2 4 06 % 10 1 13 8 .i 7? 89 91 93 95 97 99 .01 03 '05 '07 09 iorotal -Mea 980-200 Winter Flounder Pilgrim Nuclear Power Station Impingement EOxtrapolated Total 2,500......

2,000 ---1,000 50 20 82 24 16 22 90 92 94 96 9 D 00 '02 4 ' 06 'l 1O 0 1 03 15 27 89 91 93 95 97 99 '01 3 '05 07. W O0'otal -Mean 1980-2091 Alewife Pilgrim Nuclear Power Station Impingement Fxtapolated Total 100,000 7- ... ...l , O ..-....- ..._ ..- ...- ------- --.-- -.. .......10,000 1,00 23 82 24 86 88 9 92 94 96 92 00 '02 '04 U V 10 81 13 85 27 29 91. 93 95 97 99 '01 '03 '05 7 V09 iTotal -Mean 1980-2009 Figure 4, Extrapolated annual totals for typical numerical dominants impinged at Pilgrim Nuclear Power Station, 1980-2010.

10 Normandeau Associales, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Blueback Herring Pilgrim Nuclear Power Station Impingement Extrapolated Total 10,000 --- --- -'- -"-1,000 ----- --------r *- -1,0 g0 12 84 86 88 90 92 94 96 98 1)6 '02 N4 V6 '08 10 I8 83 85 87 89 91 93 91 97 99 '0V '03 '0S '0/ 9 JOToWa -Mea 1980-2009]

Cunner Pilgrim Nuclear Power Station Impingement 1,200 Ex polated Total 1,000 --- ----800 -------------I , 0, I .......................200 80 82 84 16 18 90 92 94 9 98 ' T2 '04 '06 18 0 81 13 85 817 89 91 93 95 97 99 v0 '03 65 '09 10Total -Mean 1980.2009 Tautog Pilgrim Nuclear Power Station Impingement 600 Extrapolated Total 500 ----....41 0 -.... ... ......300 ...........  

.200 100-80 82 84 86 88 90 92 94 96 98 '00 '02 '04 ' '08 t0 1 83 85 87 .8991 93 95 91 99 V1 W .05 W7 '09 JOToOW -Mean 71W872009 Figure 4. Continued.

II Normandeau Associates, Inc.11 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Grubby Pilgrim Nuclear Power Station Impingement 2500 Extrapolated Total 2,500 2,000 500 0 80 82 84 86 81 90 92 94 % 98 90 '02 '04 '6 '00 I0 ,1 83 85 87 9 91 93 95 97 99 '01 .03 ,05 .'09 1T otal -Mean 1980-20091 Rainbow Smelt Pilgrim Nuclear Power Station Impingement Extrapolated Total 10,000 -- ------------ -1,000 -= -100 10 80 82 £4 £6 88 90 92 94 96 98 '00 '02 '04 '06 '08 0£1 13 £5 £7 19 91 93 95 97 99 'o0 '03 '5'7'09 ODTotal -Mean 1980-2009 Atlantic Tomcod Pilgrim Nuclear Power Station Impingement 800 Extrapolated Total 1,600 1,400 .... .-1,400 ....1,2000 800 -....--....---.  

---- -- -6000 400 -------rj -- ---200 ..0 80 82 £4 86 B1 90 92 94 96 98 '00 '02 '04 '06 '00 10 a1 83 85 87 89 91 93 95 97 99 'VI '0S 07 09 OTotal -Mean 1980-2009 Hakes (Red and White)Pilgrim Nuclear Power Station Impingement Extrapolated Total 1,000 --------.00 ---- -~- --- ------- 7£0 £2 £4 £6 88 90 92 94 96 9£ '00 '02 '04 '06 '0£ 10-1 £3. 85 £7 £9 91 97 95 97 9 -'03- '05-'07 '09[OTolal Mean 1980.2009]

12 Normandeau Associates, Inc.12 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Lumpfish Pilgrim Nuclear Power Station Impingement Extrapolated Tolal 500 200 ----200 -- ---80 82 24 86 88 90 92 94 % 98 Q0 V0 0 '06 08 10 81 83 85 87 89 91 93 95 97 99 .01 '03 '05 07 '09[DTotal -Mean 1980.2009 Atlantic Herring Pilgrim Nuclear Power Station Impingement Exapolated Total 10,000~1 0 ---------.00...., --. ..........-_ ..80 82 84 86 11 90 92 94 96 9 '00 '02 '04 06 '01 10 81 83 85 87 19 91 93 95 97 99 0 1 '03 '03 '07 '09 ImTotal -Mean 1980-2009 Total Fish Pilgrim Nuclear Power Station Impingement Extrapolated Total 100,000 10,000 1,000 100 L 80 82 84 86 18 9D 92 94 96 98 00V2 0v V6 '03 10 81 S3 85 87 89 91 93. 95 97 99 '01 ,03 '05 07 9~To~nI -Mean 190020 Figure 4. Continued.

13 Normandeau Associates, Inc.13 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 1. Monthly extrapolated totals for all fishes collected from Pilgrim Station intake screens, January-December 2010, 2010 Common Name Species Summa__ .Jan Feb -Mar Apr May Jun Jul Aug Sep Oct Nov Dec Atlantic Silverside Menidia menidia Alewife Alma pseudoharengis Atlantic Menhaden Brevoortia tyranra Winter Flounder Pseudopleuronectes americanus Rainbow Smelt Osmerns mordat cunner Tautogolabrus adrpersus Lumpfish CyClopterus Blueback Herring Alosa aestivalis Sand Lance Ammndtes sp.Atlantic Tomcod Microgadls tomcod Striped Killifish Fundulua majalis Grubby yoxocepholts aetnaeun Atlantic Herring Clupea harengus Northern Pipefish Syngnalnfiacus American Shad Alosa sapidsima Atlantic Moonfish Selene setapinnk Little Skate Leocoraja erinacea Threespine Stickleback Gasterosteos aculeamus Windowpane Scophthalmus aquosus Smallmouth Flounder Etropur microstomas Butterfish Peprilus trtacanthus Spotted flake Uroprycis regia Radiated Shanny Ulvaria subbifjrcata Red Hake Uroplryis chws Atlantic Cod Gadu morhlu Rock Gunnel Pholis gunnefhis Mummichog Furduha heteroclitno Searobins Prionota spp.Scup Stenotoms cluYsops American Eel Anguilla rotrata White Perch Morone americana Tautog Taatoga onito Striped Bass Morone saxotilis 13,576 12,680 1,403 1,005 911 535 319 271 246 196 187 181 162 131 120 114 112 112 93 90 74 72 62 57 53 43 32 32 26 25 17 13 12 784 0 0 196 40 118 0 0 40 0 0 40 0 0 0 0 0 79 0 0 0 0 40 0 40 0 0 0 0 0 0 0 0 2,755 8,233 148 24 357 64 13 0 0 0 0 0 292 22 37 0 260 0 13 0 0 0 13 0 33 0 0 0 0 22 13 0 130 22 0 0 0 22 37 0 0 0 0 0 65 0 0 0 98 64 0 0 0 22 0 0 98 22 0 0 0 0 0 0 0 0 25 24 33 0 0 0 0 43 13 0 33 43 0 0 0 0 0 0 0 22 50 0 0 0 0 0 0 0 13 0 0 0 13 0 0 43 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 13 0 0 0 0 0 12 12,082 183 35 0 23 0 0 0 0 0 12 0 0 0 0 35 0 0 0 23 0 0 12 0 0 0 0 12 0 0 0 12 17 613 17 37 17 109 0 109 0 361 0 73 0 0 17 109 0 0 0 73 0 37 0 0 0 0 0 109 0 0 114 0 ,0 0 0 0 0 37 0 0 0 37 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 17 0 0 0 0 0 572 96 32 96 96 223 286 96 32 64 128 0 0 0 0 0 0 0 0 0 0 0 0 32 0 0 32 32 0 0 0 0 0 NumberofSpecies 33 9 8 II 13 13 2 II 10 3 6 12 14 Ectrapolated Totals 32,962 1,377 785 4,154 8,644 401 48 12,441 1,196 196 199 1,704 1,817 Number of "Collection Hours" 437.28 19.00 31.97 .22.96 34.02 60.63 30.88 65.09 53.66 29.78 45.88 19.98 23.43 Impingement Rate ýish per hour) 4.43 1.84 1.16 5.57 11.99 0.53 0.06 16.72 1.60 0.27 0.26 2.35 2.43 14 Normandeau Associates, Inc.14 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 2. Species, number, length and weight for all fish impinged at Pilgrim Station, January- December 2010.Common Name Little Skate American Eel Blueback Herring Alewife American Shad Atlantic Menhaden Atlantic Herring Rainbow Smelt Atlantic Cod Atlantic 'omcod Red Hake Spotted Hake Mummichog Striped Killifish Atlantic Silverside Threespine Stickleback Northern Pipefish Searobins Grubby Lumpfish White Perch Striped Bass Atlantic Moonfish Scup Tautog Cunner Radiated Shanny Rock Gunnel Sand Lance Butterfish Smallmouth Flounder Windowpane Winter Flounder Species Leucoraja erinacea Anguilla rostrata Alosa aestivalis Alosa pseudoharengus Alosa sapidissima Brevoortia Jyrannus Clupea harengus Osmerus mordax Gadus morhua Microgadus tonriod Urophycis chuss Urophycis regia Fundulus heteroclitus Fundulus majalis Menidia inenidia Gasterosteus aculeatus Sngnathusfuscus Prionotus spp.Moxocephalus aenaeus Cyclopterm lumpus Morone americana Morone saxatilis Selene setapinnis Stenotomus chrysops Tautoga onilis Tautogolabrus adspersus Ulvaria subbifurcata Pholis gunnellus Ammodytes sp, Peprilus triacanthus Etropus microstomus Scophthalmus aquosus Pseudopleuronectes americanus Number Length (mm) Weight (g)Collected n Mean Min Max n Mean Min Max 8 8 457.9 384 552 0 I 1 305.0 305 305 I 28.64 28.64 28,64 10 10 141.7 55 295 3 3.28 1.65 4.77 1,078 47 94.6 64 172 41 5.68 2.20 14.82 4 4 114.0 75 150 2 3,65 1.92 5.37 93 93 61.5 34 121 59 1.79 0.35 8.46 6 6 140.3 124 160 6 13.61 8.23 22.87 32 32 100,7 77 198 16 5,21 1.85 23.53 2 2 256.5 63 450 I 1.99 1.99 1.99 8 8 97.0 45 153 5 3.51 0.66 13.02 3 3 76.3 62 87 2 2.43 1,77 3.08 5 5 88.8 64 120 3 3,22 1.41 5.58 I 1 87.0 87 87 0 6 6 73.8 60 102 I 3.08 3.08 3.08 564 305 95.0 63 152 154 3.78 0.84 12,86 3 3 59.0 44 68 0 4 4 115.8 82 150 0 I 1 212.0 212 212 0 7 7 71.6 58 95 0 10 10 58.4 38 69 0 I 1 121.3 121.3 121,3 I 23.77 23.77 23.77 1 1 585.0 585 585 I 1282.00 1282.00 1282.00 7 7 49.6 46 55 0 2 2 37,5 32 43 1 0.28 0.28 0.28 1 I 320.0 320 320 1 670.00 670.00 670.00 19 19 78.3 40 160 3 39.46 10.12 70.94 2 2 100,5 76 125 0 2 2 138.0 113 163 0 8 8 152,9 110 195 1 7.06 7.06 7,06 4 4 44.8 39 51 3 0.92 0.73 1,09 4 4 88.8 48 196 2 1.73 1.00 2.45 4 4 119,8 34 214 0 39 39 90.2 44 310 4 1.36 0,95 1.78 15 Norunandeau Associates, Inc.15 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monito~ng Table 3. Annual extrapolated totals for fish found on the Pilgrim Station intake screens, 1980-2010.

Species 1980 1981 1982 1983 19841 1985 1986 19872 1988 1989 1990 1991 1992 1993 19943 19954 Alewife 99 201 262 83 88 807 261 26 464 149 1,480 250 247 1,021 123 39,884 American Eel 18 41 12 0 0 0 19 0 0 15 0 0 8 0 0 0 American Plaice 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 American Sand Lance 0 0 12 11 0 0 0 0 0 9 0 0 0 0 0 American Shad 0 0 0 0 0 0 0 0 212 0 0 0 0 0 0 0 Atlantic Cod 12 122 I1 0 0 0 33 0 23 0 0 24 10 47 42 58 Atlantic Herring 83 53 156 22 0 35 3,009 6 51 138 408 24,238 51 169 28 108 Atlantic Mackerel 0 49 0 12 0 0 0 0 24 29 13 0 0 0 12 0 Atlantic Menhaden 226 0 171 522 II 1,491 953 0 177 2,020 3,135 1,117 32 46 58 1,560 Atlantic Moonfish 0 0 0 10 8 0 0 0 0 43 0 0 14 0 0 21 Atlantic Seasnail 0 53 0 13 0 0 0 0 0 0 37 0 19 0 0 11 Atlantic Silverside 191 90,449 2,626 1,586 245 4,417 702 1,298 940 2,838 4,761 2,955 2,381 9,872 36,498 13,085 Atlantic Tonicod 63 76 221 276 157 389 174 57 11578 433 291 159 104 329 153 260 BayAnchovy 9 0 859 0 0 12 42 0 0 10 42 25 0 0 0 0 Bigeye 0 0 0 0 0 0 0 0 0 I1 0 0 0 0 0 0 Black Ruff 0 0 0 0 0 0 0 0 0 0 9 0 0 0 0 0 Black Sea Bass 0 13 0 0 0 0 10 7 0 10 0 19 14 0 0 85 Black Spotted Stickleback 0 0 0 0 0 0 0 27 0 0 0 0 0 25 33 0 BluebackHerring 46 230 251 754 34 791 63 7 222 207 1,194 298 110 295 269 1,244 Bluefish 0 0 16 0 0 0 0 0 0 0 0 0 0 0 0 0 Butterfish 0 36 0 30 15 39 0 0 0 10 1,686 24 0 12 41 42 Crevalle Jack 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Cunner 1,043 870 610 196 45 580 270 115 .97 199 210 182 28 93 77 346 Dogfish 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Flying Gurnard 0 0 0 0 0 9 0 0 0 0 0 0 0 0 0 22 Foubeard Rockling 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Fourspine Stickleback II 207 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Fourspot Flounder 87 7 10 22 0 0 0 0 12 0 10 69 0 12 0 21 Gizzard Shad 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Golden Redfish 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Goosefish 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Grubby 107 448 340 490 114 932 359 200 124 684 585 468 507 640 1,094 648 Gulf Strea Flounder 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Haddock 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Hakes (Red and White) 93. 101 125 0 8 34 27 53 23 55 0 55 14 166 23 182 16 Normandeau Associates, Inc.16 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station M6e Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 3, (continued), 1980 1981 1982 1983 19841 1985 1986 19872 1988 1989 1990 1991 1992 1993 1994, 1995, Hogchoker Little Skate Longhorn Sculpin Lumpfish Mummichog Northern Kingfish Northern Pipefish Northern Puffer Northern Searobin Ocean Pout Orange Filefish Planehead Filefish Pollock Radiated Shanny Rainbow Smelt Rock Gunnel Round Scad Sand Lance sp.Sculpin sp.Scup Sea Raven Seaboard Goby Scarobin sp.Shorthorn Sculpin Silver Hake Silver-rag Smallmouth Flounder Smooth Dogfish Smooth Flounder Spiny Dogfish Spot Spotted Hake Striped Bass Striped Cusk Eel Striped Killifish 0 0 7 0 0 0 7 12 45 15 0 0 8 25 0 38 0 160 103 75 0 0 21 0 0 23 17 0 0 144 79 122 177 8 144 1,327 177 94 78 69 20 70 60 17 0 0 0 0 0 9 0 0 0 0 0 0 0 0 0 22 0 381 119 14 30 0 45 0 0 814 236 634 1,224 29 II 30 0 53 8 0 0 0 0 0 66 0 24 79 0 0 0 0 0 0 80 23 83 11 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 11 0 0 57 35 0 22 0 0 0 8 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 8 23 0 28 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 31 0 13 0 0 10 0 0 0 0 32 II 29 120 84 0 0 0 0 0 0 13 125 46 72 674 30 78 0 0 0 97 0 28 0 0 0 0 0 0 213 0 0 24 176 28 36 51 0 120 388 47 69 13 27 0 51 13 0 0 0 0 0 0 0 0 0 0 II 23 0 0 0 0 0 0 18 0 25 56 0 50 65 70 30 0 36 9 189 1,909 1,070 370 886 387 442 0 20 0 95 9 0 0 0 24 0 0 0 0 0 0 0 0 0 64 II 0 10 0 0 0 0 0 0 49 0 16 10 0 0 0 0 0 22 8 0 0 0 0 0 0 0 0 26 0 0 0 0 0 0 0 0 0 27 0 48 0 21 0 0 0 0 0 51 0 0 0 0 0 0 0 0 0 10 0 0 0 0 56 II 0 0 12 7 0 0 0 0 0 0 0 0 41 59 42 23 0 0 599 0 0 0 12 9 23 5 12 0 19 0 0 0 0 46 8 0 0 0 0 78 92 147 48 35 0 0 0 0 0 51 122 329 177 116 12 0 11 35 20 10 0 0 0 0 30 28 116 230 180 141 42 12 0 43 23 0 48 80 68 0 0 0 0 0 0 0 0 0 0 0 14 0 0 0 23 17 107 9 39 20 43 66 141 85 372 317 8,302 9,464 2,191 62 38 210 84 107 0 0 0 0 0 20 19 0 79 0 0 0 0 0 0 159 32 8 13 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 10 0 11 0 0 23 9 32 27 I1 0 0 0 0 0 0 0 0 0 0 10 0 0 0 0 0 0 0 0 0 10 0 8 0 0 0 0 8 0 0 0 0 0 0 0 0 0 0 0 0 0 0 27 0 0 82 51 12 385 52 17 Normandeau Associates, Inc.17 Normandeau Associates, Inc, Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 3. (continued), Striped Searobins Summer Flounder Tautog Threespine Stickleback Weakfish Weitzman's Pearlside White Perch Windowpane Winter Flounder Winter Skate Yellowtail Flounder 1980 1981 1982 1983 1984' 1985 1986 1987' 1988 1989 1990 0 0 0 0 9 0 0 0 0 0 10 12 0 20 0 0 0 0 0 0 7 0 0 69 18 41 11 83 26 113 82 159 52 37 118 434 21 7 112 0 372 72 114 30 0 0 0 0 0 0 0 0 0 0 0 0 0 75 0 0 0 19 0 0 0 0 0 42 0 0 5 81 0 0 0 0 0 68 96 107 173 56 146 87 0 0 171 171 297 249 297 232 47 884 908 138 556 1,119 336 it 0 10 12 0 0 0 0 0 0 0 0 0 0 0 0 51 50 0 0 0 1991 1992 1993 19943 19954 30 0 12 0 12 0 0 0 22 0 175 93 275 50 73 19 26 47 270 124 0 0 0 0 0 0 0 34 0 0 29 88 0 24 21 103 41 133 179 232 694 787 1,181 1,018 1,628 0 0 0 0 0 0 0 27 0 0 Annual totals 4,028 95,358 8,406 6,559 1,104 12,243 9,241 3,783 6,227 10,290 15,935 32,077 5,398 23,890 50,786 62,614 Collection Time (hrs.) 687 574,8 687 763 1,042 465 806 527 525 618 919.5 930.3 774.0 673.5 737.4 607.7 Impingement Rate (fish/hour) 0.66 10.02 0.93 0.57 0.13 1.14 1.26 0.28 0.27 018 1.70 3.38 0.63 2.78 5.97 5.87 I No CWS pumps were in operation April to August 1984.2 No CWS pumps were in operation August 1987.3 No CWS pumps were in operation 9 October. 14 November 1994, 4 No CWS pumps were in operation 30 March- 15 May 1995.5 No CWS pumps were in operation 10 May. 10 June 1999.6 No CWS pumps were in operation 28 April -9 May2001.7 No CWS pumps were in operation 21 April -II May 2003.8 No CWS pumps were in operation 20 April- 8 May 2005.9 No CWS pumps were in operation 7 April -20 April 2007.is Normandeau Associates, Inc, Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 3. (continued), Mean Species Alewife American Eel American Plaice American Sand Lance American Shad Atlantic Cod Atlantic Herring Atlantic Mackerel Atlantic Menhaden Atlantic Moonfish Atlantic Seasnail Atlantic Silverside Atlantic Tomcod Bay Anchovy Bigeye Black Ruff Black Sea Bass Black Spotted Stickleback Blueback Herring Bluefish Butterfish Crevalle Jack Cunner Dogfish Flying Gurnard Fourbeard Rockling Fourspine Stickleback Fourspot Flounder Gizzard Shad Golden Redfish Goosefish Grubby Gulf Stream Flounder Haddock Hakes (Red and White)1996 1997 1998 1999' 2000 20016 2002 2003' 2004 2005' 2006 2007' 2008 2009 1980-2009 2010 216 317 158 610 2,443 1,618 334 438 145 265 240 438 75 1,261 1,800 12,680 0 0 0 0 13 0 0 0 0 0 0 15 0 0 5 25 0 0 0 0 0 0 0 36 0 0 0 0 0 0 1 0 0 0 0 0 16 0 0 0 0 0 0 0 0 0 2 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 7 120 0 0 53 42 0 113 0 61 99 192 688 56 143 86 64 53 0 13 108 181 77 48 301 51 138 549 122 0 23 0 1,006 162 0 0 0 0 0 0 0 0 0 0 0 15 0 60 7 0 2,168 1,329 1,423 42,686 64,354 3,599 53,304 119,041 10,431 277,601 15,189 154,832 721 12,528 25,691 1,403 94 0 17 273 0 86 234 0 0 20 70 0 0 23 30 114 0 0 0 0 0 13 0 10 8 0 0 0 16 0 6 0 16,615 6,303 6,773 8,577 25,665 4,987 4,430 23,149 13,107 11,590 7,993 3,362 6,167 5,349 10,630 13,576 466 72 40 302 323 278 168 19 304 1,518 616 154 289 107 313 196 0 23 0 0 0 8 148 60 0 0 0 28 23 23 44 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 15 0 57 0 38 147 188 82 0 30 0 24 0 0 50 0 0 0 0 0 0 0 34 0 0 0 0 6 0 2,462 424 134 550 5,919 229 943 1,968 2,046 646 570 352 203 30 750 271 0 0 17 0 0 0 47 0 0 0 0 0 0 0 3 0 44 1,581 42 188 0 170 0 0 31 78 29 85 28 186 147 74 0 0 0 0 0 0 17 0 0 0 0 0 0 30 2 0 332 41 101 153 348 140 59 172 240 716 384 367 247 895 305 525 0 0 0 0 13 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 27 0 0 0 0 0 0 0 0 2 0 0 0 I1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 13 0 0 0 72 0 0 0 0 10 0 0 17 6 47 0 0 0 56 122 0 0 0 0 0 17 0 0 0 0 0 27 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 17 0 0 0 0 0 0 0 I 0 0 0 0 0 13 0 0 0 0 0 0 0 0 0 0 0 1,347 405 335 628 1,105 517 1,087 237 2,257 501 306 349 374 666 595 181 0 0 0 0 27 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 15 0 0 1. 0 113 196. 106 682 182 .1,158 192 128 .202 70 72 126 159 273 154 57 19 Normandeau Associates, Inc.19 Normandeau Associates, Inc, Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 3, (continued), Mean Species 1996 1997 1998 1999 2000 20016 2002 2003 2004 2005' 2006 2007' 2008 2009 1980-2009 2010 Hogchoker Little Skate Longhom Sculpin Lumpfish Mummichog Northern Kingfish Northern Pipefish Northern Puffer Northern Searobin Ocean Pout Orange Filefish Planehead Filefish Pollock Radiated Shanny Rainbow Smelt Rock Gunnel Round Scad Sand Lance sp.Sculpin sp.Scup Sea Raven Seaboard Goby Searobin sp.Shorthorn Sculpin Silver Hake Silver-rag Smallmouth Flounder Smooth Dogfish Smooth Flounder Spiny Dogfish Spot Spotted Hake Striped Bass Striped Cusk Eel Striped Killifish 0 0 0 0 0 0 46 0 27 46 48 0 0 80 69 121 13 0 21 15 261 0 0 0 206 173 244 136 131 0 137 61 0. 0 0 36 13 0 0 0 0 0 0 0 0 0 0 0 143 55 0 187 92 28 110 99 0 105 0 0 0 0 0 I1 0 0 6 31 319 57 0 10 0 0 0 0 0 0 0 26 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 105 52 0 0 0 29 0 63 26 13 67 31 59 3,728 1,978 1,656 875 13 879 335 532 155 0 21 16 100 75 50 0 0 0 0 0 0 0 0 0 0 0 38 0 0 35 0 30,765 0 0 0 0 13 0 0 0 0 0 6 0 12 0 35 27 0 0 0 0 0 0 0 19 0 0 0 0 0 0 12 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 26 26 138 21 83 165 114 0 97 0 0 0 0 0 0 0 0 0 0 11 10 0 0 0 0 0 0 0 0 0 0 0 26 0 0 0 0 0 11 0 22 0 0 0 0 0 28 0 0 0 0 0 0 0 0 0 0 0 0 21 0 0 0 0 0 77 0 0 0 39 0 0 16 0 0 19 0 0 0 0 0 29 0 44 52 309 64 613 488 0 237 0 8 0 0 14 0 51 14 0 0 53 14 1,092 24 0 38 0 72 0 0 0 0 0 0 0 16 0 0 0 0 139 0 121 0 138 0 409 27 0 509 0 58 0 0 0 788 16 2,840 216 0 50 0 216 23 0 39 0 0 0 72 0 0 154 0 0 0 0 223 0 0 0 69 75 46 0 0 0 91 161 211 49 30 0 0 0 0 15 46 120 18 0 0 0 30 120 0 16 0 0 0 0 0 0 0 0 67 0 15 31 31 1,191 943 677 29 29 15 0 0 0 78 320 361 0 0 0 48 0 23 0 0 0 0 0 0 0 0 0 0 0 0 0 0 23 0 0 0 0 23 61 0 81 0 0 0 0 84 54 0 0 0 0 0 0 0 21 31 0 0 16 0 144 100 120 2 60 12 143 13 2 103 96 45 2 i 0 65 35 1,530 65 1 1,072 0 53 2 0 1 2 33 1 8 7 1 15 0 1 12 2 108 0 112 0 319 32 0 131 0 0 0 0 0 0 62 911 43 0 246 0 26 0 0 32 0 0 0 90 0 0 0 0 72 12 0 187 20 Normandeau Associates, Inc.20 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Madne Ecology Studies 2010 Impingement Monitoring Table 3, (continued).

Mean Species Striped S Summer Tautog Threespi Weakfisl Weiizm White P Window Winter F Winter S Yellowta 1996 1997 1998 1999' 2000 20016 2002 20037 2004 2005 2006 20079 2008 2009 1980-2009 2010 Searobins 0 83 0 61 0 0 0 0 0 0 83 21 0 0 II 0 Flounder 0 0 10 0 0 0 0 0 41 0 0 0 23 0 5 0 488 172 129 119 157 92 289 46 14 39 158 89 0 0 104 13 ne Stickleback 99 0 91 19 27 64 13 19 158 151 262 69 62 398 108 112 h 0 0 0 0 0 0 0 26 0 0 0 27 0 0 2 0 an's Peaxlsidc 0 0 0 0 0 0 0 6 0 0 16 0 0 0 5 0 erch 206 34 43 122 24 21 72 15 86 28 21 27 145 60 40 17 pane 296 65 416 434 363 162 24 13 37 135 158 42 30 301 141 93 Flounder 857 608 2,069 1,021 1,358 1,729 1,466 1,435 2,021 2,688 1.242 715 1,010 672 975 1,005 kate 0 0 0 0 0 0 0 0 0 0 0 0 0 0 I 0 ail Flounder 0 0 0 32 0 0 0 16 37 24 0 0 0 0 8 0 Annual totals 30,236 14,228 14,301 58,314 103,986 16,567 64,583 179,445 33,564 302,883 29,808 163,036 11,821 24,756 46,516 32,952 416 455 575 375.5 507 430.1 494.4 714.1 638.3 440.5 432.3 468.0 388.2 249.1 597 436.3 Collection Time (hrs.)ImpingementRate(fish/hour) 3.11 1.43 1.30 7.21 9.25 1.78 4.93 25.58 2.85 18.87 3.26 10.24 1.41 2.15 4.33 4.46 21 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 20 10 Impingement Monitoririg Pilgrim Nuclear Power Station Manne Eco1o~' Studies 2010 Impingement Monitoring Table 6. Hourly, daily, and estimated annual impingement rates for all species combined and annual dominants collected on the PNPS intake screens, 1980-2010.

Cunner 1980 0.66 4,030 (1043)(1,043)1981 10.02 95,336 Atlantic silverside (90,449)Atlantic silverside 1982 0.93 8,411(26)(2,626)Atlantic silverside 1983 0.57 6,558(,56 (1,586)Atlantic silverside 1984 0.13 1,112(25 (245)1985 1.14 12,499 Atlantic silverside (4,417)1986 1.26 9,259 Atlantic herring (3,009)1987 0.28 3,155 Atlantic silverside (1,298)1988 0.27 6,675 Atlantic tomcod (1,578)Atlantic silverside 1989 0.80 9,088(28)(2,838)Atlantic silverside 1990 1.70 15,939(47)

(4,761)1991 3.38 32,080 Atlantic herring (24,238)Atlantic silverside 1992 0.63 (2,381 (2,381)Atlantic silverside 1993 2.78 24,105(982 (9,872)Atlantic silverside 1994 5.97 50,439(36,498) 24 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 6, (continued), Year 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 Fish/Hour 5.87 3.11 1.43 1.30 7.21 9.25 1.78 4.93 25.58 2.85 18.84 3.26 10.24 1.41 2.15 Fish/Year 62,616 30,264 14,230 14,303 58,318 103,968 15,636 64,606 179,608 33,591 302,883 29,711 163,036 11,821 24,779 Dominant Species (Number/Year)

Alewife (39,884)Atlantic silverside (16,615)Atlantic silverside (6,303)Atlantic silverside (6,773)Atlantic menhaden (42,686)Atlantic menhaden (34,354)Atlantic silverside (4,987)Atlantic menhaden (53,304)Atlantic menhaden (119,041)Atlantic silverside (13,107)Atlantic menhaden (277,607)Atlantic menhaden (15,189)Atlantic menhaden (154,832)Atlantic silverside (6,167)Atlantic menhaden (12,528)Mean 4.32 46,448 Atlantic silverside 2010 4.44 33,457(13,576) 25 Normandeau Associates, Inc.25 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 7. Species collected on the Pilgrim Station intake screens, 1980-2010.

Common Name Species Alewife Alosa pseudoharengus American Eel Anguilla rostrata American Plaice Hippoglossoides plates American Shad Alosa sapidissinma Atlantic Cod Gadus morhua Atlantic Herring Clupea harengus Atlantic Mackerel Scomber scombrus Atlantic Menhaden Brevoortia rannus Atlantic Moonfish Selene setapinnis Atlantic Seasnail Liparis adlanlicus Atlantic Silverside Menidia menidia Atlantic Tomcod bficrogadus tomcod Bay Anchovy Anchoa mitchilli Bigeye Priacanthus arenatus Black Ruff Centrolophorus niger Black Sea Bass Centropristis strialo Black Spotted Stickleback Gasterosteus wheatlan Blueback Herring Atosa aestivalis Bluefish Pornatomus salatruix Butterfish Peprilus Iriacanthus Crevalle Jack Caranx hippos Curmer Tautogolabrus adspers Dogfish see below Flying Gumard Datyloplerus volitans Fourbeard Rockling Enchelyopus rimbrius Fourspine Stickleback Apeltes quadras sodes di 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 x x x x x x x x x x x x x X x x x X x X x X x X x X x x x X x X X x x X a x a a a x a a a a a x x a x a n n a .a a X X x a x a a x x a x a a x x x x x a x x a a x a x a x x a x x x a a a a a x x a X X x X x x x X X X x X x x a x X x X x X X x X X X X x x X X x x x X x 26 Normandeau Associates, Inc.26 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 7. (continued).

Common Name Fourspot Flounder Gizzard Shad Golden Redfish Goosefish Grubby Gulf Stream Flounder Haddock Hakes (red and white)Hogchoker Little Skate Longhorn Sculpin Lumpfish Mummichog Northern Kingfish Northern Pipefish Northern Puffer Northern Searobin Ocean pout Orange Filefish Planehead Filefish Pollock Radiated Shanny Rainbow Smelt Rock Gunnel Round Scad Sand Lance Species Paralichthys oblongus Dorosoma cepedianuam Sebastes norvegicus Lophius americanus Myoxocephalus aenaeus Citharichihys arctifrons Melanogramm us aeglefinus Urophyc is spp.Trinecles maculaus Leucoraja erinacea Myoxocephalus octodecemspinosus Cyclopterus lumpus Fuidulus heteroclitus Menticirrhus saxatilis Syngnathus fuscus Sphoeroides maculatus Prionoaus carolinus Zoarces americanus Alhterus schoepfii Monacanthus hispidus Pollachtus virens UMraria subbifurcata Osmerus mordax Pholis gunnellus Etrumeus teres Ammodytes sp.1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 x x x x x x x x x X a x X x x X X x x x X x X X X a X X X X X X x x x x x X a x X x x x x a a x X X X X X a x x x X a a a X a a a x x x a x x x x x a a a a X X X X X a x X X x X X X x a x a a x x a a a x a a X x X x x a a X x X X a a a a x x X a x x x x X x x a x a a x x a X X X X X X X a a a a a a a a a x a a a a a a x X X X X x X x X a a a x a x x 27 Normandeau Associates, Inc.27 Normandeau Associates, Inc.

Common Name Sculpin sp.Scup Sea Raven Seaboard Goby Searobin sp.Shorthorn Sculpin Silver Hake Silver-rag Smallmouth Flounder Smooth Dogfish Smooth Flounder Spiny Dogfish Spot Spotted Hake Striped Bass Strped Cusk Eel Striped Killifish Striped Searobins Summer Flounder Tautog Threespint Stickleback Weakfish Weitzman's Pearlside White Perch Windowpane Winter Flounder Winter Skate Yellowtail Flounder Species MyAxocephalus spp.Stenotomus chrysops Hemitripterus americanus Gobiosoma ginsburgi Prnonotus sp.Myxocephalas scorpius Merluccius bilinearas Ariomma bondi Etropas microstomus Muafelus canis Pleuronectesputnami Squalus acanthus Leiostomusianthar Urophycis reia Morone saxatilis Ophidion marginatum Fundulus majalis Prionotus evolans Poralichthys dentalus Tautoga onitis Gasterosteus aculeatus Cynoscion regalis Maurolicus weitmani Morone americana Scophthalmus aquosus Pleuronectes americanus Leucoraja ocelata Limandaferruginea 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 x x x x x X X X X X x X X X x x x x x x X X x x x a X X x x x X x x X X x S x x S x S X x x x x S X x x x x x x X x x x x x x x x x x X x S S S x S x x S x S x x x x x S S S x x x x S X S S a x x a x x x a x x x a x a.5 x x a a x x a a x a x x x x x x x x x x x x 28 Norrnandeau Associates, Inc.28 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Moriitoring Pilgrim Nuclear Power Staflon Marine Ecology Studies 2~lO Impingement Monitoring Table 7. (continued), Common Name Alewife American Eel American Plaice American Shad Atlantic Cod Atlantic Herring Aflantic Mackerel Atlantic Menhaden Atlantic Moonfish Atlantic Seasnail Atlantic Silverside Atlantic Tomcod Bay Anchovy Bigeye Black Ruff Black Sea Bass Black Spoted Stickleback Blueback Herring Bluefish Butterfish Crevalle Jack Cunner Dogfish Flying Gurnard Fourbeard Rockling Fourspine Stickleback Species Alosa pseudoharengus Anguilla rostrata Hippoglossoides platessoides Alosa sapidissima Gadus morhua Clupea harengus Scomber scombrus Brevoortia lyrannus Selene setapinnis Liparis atlanticus Menidia menidia Microgadus tomcod Anchoa mitchilli Priacanthus arenaius Centrolophorus niger Centropristis striata Gasterosteus wheatlandi Alosa aestivalis Pomatomus saltatrix Peprilus triacanthus Caranx hippos Tautogolabrus adspersus see below 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 x x x x x x X x X x X x x x x x x x x a a x a x a x x x x x a x x x X x X X a a a a x x x x x x x x X X x X x X a a a x a x x x x a x a x a a x a a x x a x x X X X x a a a a x a x X a a a a X X a a a a a a x X X x a a a a x a x X X X x x x a a a x x a a a x X Dactylopterus volitans Enchelyopus cimbrius Apeltes quadracus X x x 29 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 7. (continued), Common Name Fourspot Flounder Gizard Shad Golden Redfish Species Paralichihs oblongus Dorosoma cepedi&num Sebasies norvegicus 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 x x x x x x x Goosefish Grubby Gulf Stram Flounder Haddock Hakes Hogchoker Little Skate Longhorn Sculpin Lumpfish Mummichog Northern Kingfish Northern Pipefish Nordern Puffer Northern Searobin Ocean pout Orange Filefish Planehead Filefish Pollock Radiated Shanny Rainbow Smelt Rock Gunnel Round Scad Sand Lance Lophius arnericanus Myoxocephalus aenaeus Citharichilhs arcnfrorm Melonogrommus aeglefinus Uroptycir spp.Trinectes maculatus Leucoraja erinacea yvoxocephalus octodecemspinosus Cyclopterns lumpus Fundulus heterocitus Menticirrhus saatilis Syngnathusfuscus Sphoeroides maculatus Prionotus carolinus Zoarces americanus Aluterus schoepfii Monacanthus hispidus Pollachius virens Ulvaria subbifu'cata Osmerus mordax Pso/is gannellus Etrwneus teres Ammodyles sp.x x x X x X S x x x x x X X x S S x x x u x x x x x x x x x x x x x x x x x x x x S S x x x x x x x a a a a x x x a a x x a x x x a a x x x X X x X X x x A x x X X x x X X X X a x X x X a x x X x S x a x a x a x x x a x a x x x x S x x x x x a a a x x x x a x a x x x x a a x X X x X x x X .X 30 Normandeau Associates, Inc.30 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 7. (continued).

Common Name Sculpin sp.Scup Sea Raven Seaboard Goby Searobin sp.Shonhom Sculpin Silver Hake Silver.rag Smallmouth Flounder Smooth Dogfish Smooth Flounder Spiny Dogfish Spot Spoited Hake Striped Bass Striped Cusk Eel Striped Killifish Striped Searobins Summer Flounder Tautog Threespine Stickleback Weakfish Weitzman's Peariside White Perch Windowpane Winter Flounder Winter Skate Yellowtail Flounder Species Mfyoxocephalus spp.Stenolomus chrysops Hem itripterus americanus Gobiosoma ginsburgp Prionolus sp.Myxocephalus scorpius Merluccius bilinearus Ariomma bondi Efropus microstomus Mustelus canis Pleuronectes putnami Squalus acanthus Leioslomusxanthurus Urophycis regia Morone saxatilis Ophidion marginatum Fundulus majalis Prionotus evolans Paralichthys dentalus Tautoga onifis Gasterosteus aculeatus C)yoscion regalis Maurolicus weifmani Morone americana Scophthalmus aquosus Pleuronectes americanus Leucoraja ocelata Limandaferruginea 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 a x x x x x x x x x x x x x x x x x X x x x x x x x a x x x X a a a a a a x a x a x x X x a a x a x a a x x X x x x x x a a x a x x x x a a x a a X x X X x a x X a. x x a a x a a x a x x a a x a x a a a x x a a a a X X X x a a a x X x x X X x X 31 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 8. Monthly extrapolated totals for invertebrates impinged on the PNPS intake screens, January- December 2010.2010 Common Name Species Summa!Y Jan Feb Mar Apt May Jun Jul Aug Sep Oct Nov Dc Ribbon worm Nemertean 129 0 0 33 0 0 0 0 0 0 0 0 96 Nereis Nereissp.

916 0 673 163 43 0 0 0 0 0 0 37 0 Nephtys Nephtyssp.

325 0 0 325 0 0 0 0 0 0 0 0 0 Squid Loligo pealeii 455 0 0 0 0 I11 234 23 70 0 17 0 0 Horseshoe Crab Limuhapolyphemus 61 0 0 0 0 25 24 12 0 0 0 0 0 Sevenspine Bay Shrimp Crangon septemspinosa 6,368 1,763 2,250 649 1,503 62 0 0 0 0 0 109 32 American Lobster flomarys americanus 350 40 0 65 0 123 0 0 0 0 17 73 32 Spider Crabs Libinia spp. 25 0 0 0 0 0 0 0 0 25 0 0 0 Cancer Crabs Cancer spp. 2,301 235 337 130 106 234 210 69 14 121 244 505 96 Blue Crabs Callinectes sapidus 25 0 0 0 0 0 0 0 0 25 0 0 0 Green Crabs Carctnomaepas 999 275 22 33 64 62 24 46 14 49 65 217 128 Lady Crabs Ovalipesocellatas 218 0 0 98 22 0 0 12 0 0 49 37 0 Starfish Asterias spp. 282 40 0 0 43 86 24 0 0 25 0 0 64 Number of Species 13 5 4 8 6 7 5 5 3 5 5 6 6 Extrapolated Totals 12,454 2,353 3,282 1,496 1,781 703 516 162 98 245 392 978 448 Number of "Collection Hours" 437 19 32 23 34 61 31 65 54 30 46 20 23 Impingement Rate (fish per hour) 1.41 3.68 5.29 2.61 2.70 1.04 0.71 0.35 0.28 0.34 0.70 1.70 1.07 32 Nonnandeau Asso~iate.~

Inc.32 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 9. Extrapolated totals for invertebrates collected at Pilgrim Station from the intake screens, January- December, 1980- 2010.Species American Lobster Homarus americanus Amphipod Amphipoda Arctic Lyre Crab Hyvas coarciatls Barnacle Cirripedia Bloodwonrm G era sp.Blue Crab Callinecles sapidus Blue Mussel Myilus edulls Brittle Star Ophiuroidea Cancer Crab Cancer 5pp.Caridean Shrimp Caridea Clam Worm Nereis spp.Common Periwinkle Littorina litlorea Gammarid Shrimp Gammarus spp.Glass Shrimp Dichelopandulus leptocerus Green Crab Carcinus maenas Hermit Crab Paguridae Horseshoe Crab Limuluspo4.phemus Isopod Isopoda Japanese Shore Crab Hemigraphussanguineus Jellyfish Cnidaria Lady Crab Ovalipes ocellatus Mysid Shrimp ,ysidacea Mantis Shrimp Squia empusa Nephtys Nephtys spp.Nadibranch Nudibranchia Oligochaele worm Orbinlldae Penaeid Shrmip Penaeidae Polychaete worm Polychaeta Ribbon worm Nemerlean Rock Crab Cancer irroratus Roundworm Nemuatoda Sea Anenome Actinaria Sea Urchin Echinoidea Sevenspine Bay Shrimp Crangon septenispinosa Sofishell Clam *ya arenaria Spider Crab Libinia spp.Squid Loligo spp.Starfish Asterias spp.Tunicate Tunicata Twelve-scaled Worm Lepidodontus spp, Unidentified crab 1980 1981 1982 1983 7,482 3,828 4,596 6,044 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 7,494 44,708 154266 0 0 0 0 0 0 0 0 0 0 0 0 0 0 8,589 6,521 0 8,213 0 0 0 0 0 0 0 0 0 11,177 0 0 4,582 3,828 4,279 4,664 0 0 0 0 3,610 4,167 3,962 11,906 0 0 0 0 0 0 0 0 0 744 0 940 8,939 8,975 6,125 5,304 0 0 0 0 0 0 6,736 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 11,207 0 0 10,427 8,975 0 3,891 5,352 2,836 4,210 0 0 0 0 9,771 0 0 0 6,858 8,259 15,661 8,952 6,657 11,038 4,893 7,199 0 0 0 9,682 0 0 0 0 7,988 16,567 13,473 3,881 3,596 6,849 5,31 .6,768 0 0 0 0 0 0 0 0 0 0 10,463 0 1984 0 0 0 0 0 0 5,966 0 0 0 0 0 0 0 1,750 0 993 0 0 0 5,243 0 0 0 0 0 0 0 0 3,142 6,711 0 3,772 2,584 0 0 4,506 482 0 0 0 1985 5,483 0 0 0 0 0 6,598 0 0 0 0 0 0 0 4,490 0 4,617 9,124 0 0 4,859 0 0 0 0 0 0 7,159 0 6,701 0 0 8,483 23,243 0 0 5,327 7,766 0 0 0 1986 1987 1988 1989 112 0 46 323 0 0 233 53 0 0 0 is 0 0 0 0 0 0 0 0 11 0 0 0 9,195 49,823 4,891 3,309 0 0 23 0 0 49 0 158 0 0 0 446 58 149 133 329 9 30 24 0 0 0 0 0 0 0 0. 0 447 220 311 362 0 0 24 0 842 .88 718 721 11 542 266 170 0 0 0 0 0 0 0 0 263 31 0 341 0 0 0 0 0 0 7 0 0 0 0 0 236 2,767 2,684 246 0 0 0 0 0 0 0 0 99 5,004 5,530 638 74 1,558 348 90 446 2,767 1,725 1,215 0 0 79 0 59 0 196 0 45 1,215 222 855 1,778 5,903 4,043 3,456 0 0 0 0 11 0 0 0 240 39 328 660 302 35 2215 2,934 0 0 0 0 0 0 7 0 0 36 0 0 Total 116,669 251,997 98,736 85,257 35,150 93,850 14,237 70,218 24,051 16,354 33 Normandeau Associates, Inc.33 Normandean Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 9. (continued), Species American Lobster Homarus americanus Amphipod Amphipoda Arctic Lyre Crab Hyas coarctatus Barnacle Cirripedia Bloodworm Glycera sp.Blue Crab Callinectes sapidus Blue Mussel Mytilus edulis Brittle Star Ophiuroidea Cancer Crab Cancer spp.Caridean Shrimp Caridea Clam Worm Nereis spp.Common Periwinkle Littorina Iittorea Gammarid Shrimp Gammarus spp.Glass Shrimp Dichelopandulus leptocen Green Crab Carcinus maenas Hermit Crab Paguridae Horseshoe Crab Limuluspolyphemus Isopod Isopoda Japanese Shore Crab llemigraphus sanguineus Jellyfish Cnidaria Lady Crab Ovalipes ocellatus Mysid Shrimp k,,sidacea Mantis Shrimp Squila empusa Nephtys Nephtys spp.Nudibranch Nudibranchia Oligochaete worm Orbimidae Penacid Shrmip Penaeidae Polychaete worm Polchaeta Ribbon worm Nemertean Rock Crab Cancer irroratus Roundworm Nematoda Sea Anenome Actinaria Sea Urchin Echinoidea Sevenspine Bay Shrimp Crangon septemspinosa Sofishell Clam Mya arenaria Spider Crab Libinia spp.Squid Loligo spp.Starfish Asterias spp.Tunicate Tunicata Twelve-scaled Worm Lepidodontus spp.Unidentified crab S 1990 1991 1992 410 631 1,050 0 0 0 10 12 10 0 10 0 0 0 0 12 0 0 209 742 14 0 0 0 0 0 0 0 0 0 10 70 226 0 0 0 14 0 0 0 0 0 272 597 622 9 32 0 340 421 1,128 9 73 106 0 0 0 0 0 0 90 466 44 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 25 45 10 42 565 893 215 0 0 0 0 0 58 72 63 61 1,019 1,573 2,825 0 0 0 0 0 0 605 296 445 1,661 1,812 61 0 0 0 0 0 0 0 0 0 1993 1,554 0 22 0 0 0 0 0 0 0 648 0 0 0 1,013 0 1,616 50 0 0 49 0 0 0 0 0 0 100 155 1,207 34 0 61 1,705 0 0 360 675 0 0 0 1994 993 0 13 0 48 0 35 0 0 9 1,086 0 0 0 1,643 0 519 13 0 0 10 33 0 0 0 48 0 0 18 813 0 0 95 6,876 24 0 760 351 0 0 0 1995 619 0 0 0 31 0 0 0 0 0 1,417 0 0 0 1,395 0 183 76 0 0 40 0 0 0 0 0 0 0 64 1,607 0 0 82 5,740 0 0 2,270 147 0 0 0 1996 986 0 0 0 21 0 0 0 0 0 510 0 0 0 1,358 0 190 27 0 0 44 0 13 0 0 21 0 40 0 1,337 0 19 60 16,342 0 0 309 113 0 0 0 1997 383 0 0 0 0 0 34 0 0 0 96 0 0 0 906 0 131 0 0 0 64 0 55 0 312 0 0 0 27 244 0 0 71 907 0 0 343 534.0 0 0 1998 429 0 0 0 0 0 0 0 0 0 97 0 0 0 550 0 71 10 0 0 53 0 0 0 0 0 0 0 0 113 0 0 31 9,570 0 0 1,145 222 0 0 0 1999 606 0 0 0 0 0 0 0 0 0 420 0 0 0 950 0 37 0 0 0 35 0 15 16 26 0 0 26 78 360 0 0 31 7,861 0 0 1,013 1,885 10 0 0 Total 5,352 7,702 6,934 9,249 13,390 13,671 21,389 4,107 12,290 13,371 34 Normandeau Associates, Inc, Pilgrim Nuclear Power Station Marine Ecology Studies 20 10 Impingement Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Impingement Monitoring Table 9, (continued), 1980-2009 Species 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 Mean 1 2010 American Lobster Homarusamencanus 631 112 145 321 140 1,025 278 519 54 0 1)93 350 Amphipod Amphipoda 0 0 0 0 0 0 0 0 0 0 10 0 Arctic Lyre Crab Hyas coarctatus 0 13 0 0 0 0 0 0 0 0 3 0 Barnacle Cirripedia 0 0 0 0 0 0 0 0 0 0 0 0 Bloodworm Glycerasp.

0 1,206 274 61 26 45 51 76 36 97 1,527 282 Tunicate Tunicata 0 0 0 0 0 0 0 0 0 0 2 0 Twelve-scaled Worm Lepidodontus ipp. 16 0 0 0 0 0 0 0 0 0 I 0 Unidentified crab 0 0 0 0 0 0 0 0 0 0 349 0 Total 36,939 12,622 10,609 11,979 16,990 12,428 4,661 4,624 4,883 9,667 34646 12,454 35 Normandeau Associates, Inc.35 Normandeau Associates, Inc.

 

92 14 Numbers of equivalent adult Atlantic menhaden estimated from entrainment and impingement data at PNPS, 1980-2010.

92 15 Numbers of equivalent adult Atlantic menhaden estimated from survival adjusted entrainment and impingement data at PNPS, 1980-20 10. 93 16 Numbers of equivalent adult Atlantic herring estimated from entrainment and impingement data at PNPS, 1980-2010.

93 17 Numbers of equivalent adult Atlantic cod estimated from entrainment and impingement data at PNPS, 1980-2010.

94 18 Numbers of equivalent adult Atlantic cod estimated from survival adjusted entrainment and impingement data at PNPS, 1980-20 10. 94 LIST OF TABLES TABLE PAGE I PNPS ichthyoplankton entrainment values for 2010 by species category and month used to determine unusually high densities.

8-10 2 Species of fish eggs (E), larvae (L), and juveniles (J) obtained in ichthyoplankton collections from the Pilgrim Nuclear Power Station discharge canal, January-December 2010. 51 3 Ichthyoplankton densities (number per 100 m 3 of water) for each samp-ling occasion during months when notably high densities were recorded, January-December 2010. Densities marked by + were unusually high based on values in Table 1. Number in parentheses indicates percent of all previous values during that month which were lower. 52-56 4 Species of fish eggs (E) and larvae (L) collected in the PNPS discharge canal, 1975-2010.

57-60 iii Nonnandeau Associafes, Inc.iii Normandeau Associates, Inc.

TABLE PAGE 5 Numbers of winter flounder eggs and larvae entrained at PNPS annually by stage, 1980-20 10. Number and weight of equivalent age 3 adults calculated by four methods is also shown. Estimates based on normal operation flow except where indicated.

95 6 Numbers of winter flounder eggs and larvae entrained adjusted for survival at PNPS by stage, 1980-2010.

Numbers and weights of equivalent age 3 adults calculated by three methods is also shown. Estimates based on normal operational flow. 96 7 Numbers of winter flounder impinged at PNPS annually, 1980-20 10.Numbers and weights of equivalent age 3 adults calculated by three methods is also shown. 97 8 Numbers of winter flounder impinged adjusted for survival at PNPS, 1980-2010. Numbers and weights of equivalent age 3 adults calculated by three methods is also shown. 98 9 Numbers of cunner eggs and larvae entrained at PNPS annually, 1980-2010. Numbers and weights of equivalent adults calculated by two methods are also shown. Estimates based on normal operational flow. 99 10 Numbers of cunner eggs and larvae entrained adjusted for survival at PNPS, 1980-2010.

Numbers and weights of equivalent adults calculated by two methods are also shown. Estimates based on normal operational flow. 100 I I Numbers of cunner impinged at PNPS, 1980-2010.

Numbers and weights of equivalent adults calculated by two methods are also shown. Estimates based on normal operational flow. 101 12 Numbers of cunner impinged adjusted for survival at PNPS, 1980-2010.

Numbers and weights equivalent adults calculated by two methods are also shown. Estimates based on normal operational flow. 102 13 Numbers of Atlantic mackerel eggs and larvae entrained at PNPS annually, 1980-2010.

Numbers and weights of equivalent age I and age 3 fish are also shown. Estimates based on normal operational flow. 103 iv Normandeau Associates, Inc.iv Normandeau Associates, Mc.

TABLE PAGE 14 Numbers of Atlantic mackerel impinged at PNPS, 1980-2010.

Numbers and weights of equivalent age 3 fish calculated by two methods are also shown. Estimates based on normal operational flow. 104 15 Numbers of Atlantic menhaden eggs and larvae entrained at PNPS annually, 1980-2010.

Numbers and weights of equivalent age 2 and age 3 fish Calculated by two methods also shown. Estimates based on normal operational flow. 105 16 Numbers of Atlantic menhaden eggs and larvae entrained adjusted for survival at PNPS, 1980-2010.

Numbers and weights of equivalent age 2 and age 3 fish calculated by two methods are also shown. Estimates based on normal operational flow. 106 17 Numbers of Atlantic menhaden impinged at PNPS annually, 1980-2010.

Numbers and weights of equivalent age 2 and 3 adults calculated by two methods are also shown. Estimates based on normal operational flow. 107 18 Numbers of Atlantic herring larvae entrained at PNPS annually, 1980-2010.

Numbers and weights of equivalent age I and age 3 fish calculated by two methods are also shown. 108 19 Numbers of Atlantic herring impinged at PNPS annually, 1980-2010.

Numbers and weights of equivalent age 3 fish calculated by two methods are also shown. 109 20 Numbers of Atlantic cod eggs and larvae entrained at PNPS annually, 1980-2010.

Numbers and weights of equivalent age 2 fish calculated by two methods are also shown. 110 21 Numbers of Atlantic cod impinged at PNPS annually, 1980-2010.

Numbers and weights of equivalent age 2 fish calculated by two methods are also shown. 111 22 Numbers of Atlantic cod impinged adjusted for survival at PNPS, 1980-20 10.Numbers and weights of equivalent age 2 fish calculated by two methods are also shown. 112 23 Numbers of lobster entrained and impinged at PNPS annually, 1980-2010.

Numbers of equivalent adults (82 mm) are also shown. 118 V Normandeau Associates, Inc.V Normandeau Associates, Inc.

LIST OF APPENDICES APPENDIX A* Densities of fish eggs and larvae per 100 m 3 of water recorded in the PNPS discharge canal by species, date, and replicate, January-December 2010.B* Geometric mean monthly densities and 95% confidence limits per 100 m 3 of water for the dominant species of fish eggs and larvae entrained at PNPS, January-December 1981-2010.

*Available upon request.vi Normandeau Associales, Inc.vi Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring SECTION I

 

Sampling of entrained ichthyoplankton at PNPS in 2010 followed the revised protocol initiated in April 1994. In January, February, and October through December three samples were taken every other week each month, weather permitting, for a total of six per month. In March through September samples were taken three times every week in conjunction with the impingement monitoring study, except on March I S and 3 rd due to a severe storm and September 3 rd due to Hurricane Earl moving up along the New England coast.A total of 40 species of fish were represented in the January-December samples, slightly higher than the 35-year mean (39 species).

Winter-early spring (January -April) samples were dominated by Gadidae-Glyptocephahts, Labridae-Limanda, windowpane, fourbeard rockling, and American plaice eggs along with sand lance, grubby, rock gunnel, and Atlantic seasnail larvae. Late spring-early summer collections, taken from May through July, were dominated by tautog-cunner-yellowtail flounder, fourspot flounder-windowpane, fourbeard rockling-hake-butterfish, and Atlantic mackerel eggs along with cunner, winter flounder, radiated shanny, tautog, fourbeard rockling, yellowtail flounder, and Atlantic menhaden larvae. Late summer-autumn collections (August -December) were dominated by the tautog-cunner-yellowtail, silver hake-scup-weakfish, fourspot flounder-windowpane, and fourbeard rockling-hake-butterfish egg groups, along with cunner, tautog, Atlantic menhaden, hake, fourbeard rockling, fourspot flounder, windowpane, and silver hake larvae.Comparisons of ichthyoplankton densities over the 1975-2009 time series suggested that, in most cases, numbers in 2010 were consistent with those recorded since sampling began at PNPS in 1975. Species that appeared abundant in 2010 compared with past years included searobin and fourspot flounder-windowpane eggs and tautog larvae. In contrast, Atlantic mackerel eggs and larval seasnail, rock gunnel, and sand lance densities were relatively low.Unusually high entrainment densities, based on historical results (defined under PNPS's sampling plan), were identified on 76 occasions in 2010 and involved six species of eggs and ten species of larvae. High abundance episodes were generally scattered among species and over time, and were of short duration.Entrainment and impingement of winter flounder, cunner, Atlantic mackerel, Atlantic menhaden, Atlantic herring, and Atlantic cod were examined in some detail dating back to 1980 I Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring using equivalent adult (EA) procedures.

These estimates were compared to commercial and recreational landings, and local stock size estimates where available.

Equivalent adult estimates for winter flounder eggs and larvae entrained in 2010 were 6,293 age 3 adults compared with a 1980-2009 average of 13,629 assuming 100% entrainment mortality.

When entrainment survival was included in the calculations, estimates decreased to 4,292 age 3 adults in 2010 compared to a time series average of 9,206. An additional 112 age 3 equivalent adults were estimated from the number of winter flounder impinged in 2010. The number of equivalent age 3 adults impinged declined to 88 when impingement survival was included in the calculations.

The 2010 cunner equivalent adult estimates decreased to 128,357 fish when entrainment survival was included in the calculations.

An additional 442 equivalent adult cunner were impinged in 2010 that declined to 393 equivalent adults after adjustment for impingement survival.

Atlantic mackerel equivalent adults attributable to entrainment in 2010 amounted to 316 age 1 fish or 114 age 3 fish based on two sets of survival values. Atlantic mackerel are swift swimmers and are not often impinged at PNPS. EA values for Atlantic menhaden were 1,004 age 2 fish in 2010 assuming 100% entrainment mortality, with an additional 355 age 2 equivalents estimated to have been impinged in 2010. The number of age 2 menhaden declined to 532 fish when adjusted for entrainment survival.

Atlantic menhaden are sensitive to impingement and were assumed to have zero survival.

Atlantic herring larvae entrained in 2010 were equivalent to 8,043 age 1 or 3,260 age 3 fish. Impingement, generally contributed little to herring equivalent adults at PNPS. Atlantic herring were assumed to have zero entrainment and impingement survival.

Lastly, EA values for Atlantic cod were 664 age 2 fish, with an additional 36 equivalent age 2 Atlantic cod estimated to have been impinged in 20 10 at PNPS. Atlantic cod were assumed to have zero entrainment survival.

Equivalent age 2 cod declined to 32 when impingement survival was included in the calculations.

Twenty-seven lobster larvae were collected at PNPS during the January-December 2010 entrainment sampling period, resulting in an estimated total of 766,221 entrained larvae. The equivalent adult (82 mm CL) estimates for lobster larvae entrained in 2010 were 15 lobsters with an additional 238 equivalent adult lobsters attributed to impingement.

2 Normandeau Associates, Inc.2 Normandeau Associales, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 20 10 Entraim-nent Monitoring SECTION II INTRODUCTION This report summarizes the results of ichthyoplankton entrainment sampling conducted at the Pilgrim Nuclear Power Station (PNPS) from January through December 2010 by Normandeau Associates, Inc. for Entergy Nuclear uhder Contract No. 50014600, in compliance with environmental monitoring and reporting requirements of the PNPS NPDES Permit (U.S.Environmental Protection Agency and Massachusetts Department of Environmental Protection), Included here is a brief summary of the dominant taxa collected over the course of the year, a review of long-term trends for the dominant fish eggs and larvae, and an assessment of numbers entrained for six key species, winter flounder (Pseudopleuronectes americanus), cunner (Tautogolabrus adspersus), Atlantic mackerel (Scomber scombrus), Atlantic menhaden (Brevoortia tyrannus), Atlantic herring (Clupea harengus), and Atlantic cod (Gadus morhua).SECTION III METHODS AND MATERIALS Monitoring Entrainment sampling at PNPS, begun in 1974, was originally completed twice per month during January and February, October-December; weekly during March through September; in triplicate at low tide. The sampling regime was modified beginning in April 1994;the revised program exchanged replication for improved temporal coverage and has been followed every year since then. In January, February, and October through December during two alternate weeks each month single samples were taken on three separate occasions.

Beginning with March and continuing through September single samples were taken three times every week. During autumn and winter months when sampling frequency was reduced, sampling was postponed during onshore storms due to heavy detrital loads. The delayed sample was taken during the subsequent week; six samples were ultimately taken each month.To minimize costs, sampling was linked to the impingement monitoring program so that collections were made Monday morning, Wednesday afternoon, and Friday night regardless of tide (see Impingement Section).

All sampling was completed with a 60-cm diameter plankton net streamed from rigging mounted approximately 30 meters from the headwall of the discharge canal (Figure 1). In instances where the net rigging mount failed, a temporary rigging was 3 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrairunent Monitoring installed and sampling continued.

Standard mesh was 0.333-mm except from late March through late May when 0.202-mm mesh was employed to improve retention of early-stage larval winter flounder.

Sampling time in each case varied from 8 to 30 minutes depending on tide, higher tide requiring a longer interval due to lower discharge stream velocities.

In most cases, a minimum quantity of 100 m 3 of water was sampled although at astronomically high tides it proved difficult to collect this amount even with long sampling intervals since the net would not inflate in the low current velocity near high tide. Exact filtration volumes were calculated using a General Oceanics Model 2030R digital flowmeter mounted in the mouth of the net. Near times of high water a 2030 R2 rotor was employed to improve sensitivity at low velocities.

All samples were preserved in 10% Formalin-seawater solutions and returned to the laboratory for microscopic examination.

A detailed description of laboratory and analytical procedures appears in MRI (1988) and NAI (2008). As in past years, larval winter flounder were enumerated in four developmental stages as follows: Stage I -from hatching until the yolk sac is fully absorbed (2.3-2.8 mm TL).Stage 2 -from the end of stage 1 until a loop or coil forms in the gut (2.6-4 mm TL).Stage 3 -from the end of stage 2 until the left eye migrates past the midline of the head during transformation (3.5-8 mm TL).Stage 4 -from the end of stage 3 onward (7.3-8.2 mm TL).Similarly larval cunner (Tautogolabrus adspersus) were enumerated in three developmental stages: Stage 1 -from hatching until the yolk sac is fully absorbed (1.6-2.6 mm TL).Stage 2 -from the end of stage 1 until dorsal fin rays become visible (1.8-6.0 mm TL).Stage 3 -from the end of stage 2 onward (6.5-14.0 mm TL).Samples were examined in their entirety for larval American lobster (Homarus americanus).

When collected these were staged following Herrick (1911).Unusual Entrainment Levels When the Cape Cod Bay ichthyoplankton study was completed in 1976, provisions were added to the entrainment monitoring program to identify unusually high densities of fish eggs and larvae. Prior to 1994 "unusually abundant" was defined as any mean density, calculated over 4 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring three replicates, which was found to be 50% greater than the highest mean density observed during the same month from 1975 through to the current year. Restricting comparisons to monthly periods damped the large seasonal variation so readily apparent with ichthyoplankton and allowed tracking densities as each species' season progressed.

On a month-by-month basis for each of the numerically dominant species all previous mean densities over three replicates (1974-1993) were examined and tested for normality following logarithmic transformation.

Single sample densities obtained from 1994-2009 were added to the pool within each month. Where data sets (for example, mackerel eggs taken in June) fit the lognormal distribution, then "unusually large" was defined by exceeding the overall log mean density plus 2 or 2.58 standard deviations.'

Log densities were back-transformed to make them easier to interpret thus providing geometric means. In cases where data sets did not fit the lognormal distribution (generally months when a species was frequently but not always absent, i.e., many zeros occurred), the mean and standard deviation was computed using the delta-distribution (see for example Pennington 1983). The same mean plus standard deviation guideline was applied.The decision to rely on 2 standard deviations or 2.58 standard deviations was based on the relative importance of each species. The more critical criterion was applied to species of commercial, recreational, or biological interest, the less critical to the remaining species (i.e., relatively greater densities were necessary to flag a density as unusual).

Species of commercial, recreational, or biological interest include Atlantic menhaden, Atlantic herring, Atlantic cod, tautog and cunner (the labrids; Tautoga onitis and Taulogolabrus adspersus), sand lance (Ammodytes sp.), Atlantic mackerel, windowpane (Scophthalmus aquosus), American plaice (Hippoglossoides platessoides), and winter flounder.

Table I provides summary data for each species of egg and larva by month within these two categories showing the 2010 "unusually high" levels.A scan of Table I will indicate that, in cases where the long-term mean amounts to I or 2 eggs or larvae per 100 mi, the critical level is also quite small. This situation occurred during'Normal distribution curve theory states that 2.5% of the measurements in a normally distributed population exceed the mean plus 1.96 standard deviations  

(= s, we rounded to 2 for simplicity), 2.5% lie below the mean minus 1.96 standard deviations.

Stated another way 95% of the population lies within that range and 97.5% lies below the mean plus L.96s. Likewise 0.5% of measurements exceed the mean plus 2.58s, 99% lie within the range of the mean X 2.58s, 99.5% lie above the mean + 2.58s.: 5 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring months when a given species was obviously uncommon and many zeros were present in the data set with an inherent small standard deviation.

The external reference distribution methodology of Box et al. (1975) was also employed, This procedure relies on a dotplot of all previous densities for a species within each month to produce a reference distribution.

Densities exceeding either 97.5 or 99.5% of the reference set values were considered unusually high with this procedure.

6 Normandeau Associates, Inc.6 Normandeau Associates, Inc.

y 2 z C-t t12~II 0 0 5-rj2 C-0 C., 0 0~t'i 0 2~0 0 0.C, 0 C, Figure 1. Aerial photograph of the entrainment sampling station in PNPS discharge canal.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Table 1. PNPS ichthyoplankton entrainment values for 2010 by species category and month used to determine unusually high densities.

See text for details, Densities per Long-term Mean + Mean + Previous High 100 m 3 of water: Meant 2 std.dev. 2.58 std.dev. (Year_January LARVAE Atlantic herring2 Sculpin Rock gunnel Sand lance 2 February LARVAE Atlantic herring2 Sculpin Rock gunnel Sand lance 2 March EGGS American plaice 2 LARVAE Atlantic herring 2 Sculpin Seasnails Rock gunnel Sand lance 2 Winter flounder 2 AprilI EGGS American plaice 2 LARVAE Atlantic herring Sculpin Seasnails Radiated shanny Rock gunnel Sand lance 2 Winter flounder 2 May EGGS Gadidae-Glyptocephalus Labrids 2 Atlantic mackerel 2 Windowpane 2 American plaice 2 0.2 0.9 4.0 5 0.5 2 5 16 2 2 17 0.6 10.7 12.5 0.4 3 2 15 6 5 4 21 7 0.7 29 3 3 388 0.7 32 3 998 12.2 7 65 177 608 1 723 391 8 7 142 3.7 (2006)17.6 (2009)78.1 (2002)337.0 (1996)5.8 (2002)341.1 (2006)133.0 (1999)372.9 (1995)19.0 (1977)30.9 (2005)369.9 (1997)16.9 (2002)882.2 (1997)2242.0 (2005)16.2 (1997)70.3 (1978)83.1 (2005)386.2 (1985)98.1 (1974)83.9(2002) 121.1 (1992)2590.6 (1994)198.3 (1974)63.5(2002) 34050.0 (1974)19203.0 (1995)603.9 (2008)162.4 (2007)2.6 36 18 9 2 3.1 3514 4031 147 15 8 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Table I (continued).

Densities per 100 m 3 of water: Long-term Mean +Mean' 2 std.dev.Mean +2.58 std.dev.Previous High (Year)May LARVAE Atlantic herring Fourbeard rockling Sculpin Seasnails Radiated shanny Sand lance 2 Atlantic mackerel Winter flounder 2 June EGGS Atlantic menhaden 2 Searobins Labrids 2 Atlantic mackerel 2 Windowpane 2 2 American plaice LARVAE Atlantic menhaden 2 Fourbeard rockling Hake Cunner 2 Radiated shanny Atlantic mackerel 2 Winter flounder 2 July EGGS Atlantic menhaden 2 Labrids 2 Atlantic mackerel 2 Windowpane 2 LARVAE Atlantic menhaden 2 Fourbeard rockling Hake Tautog, Cunner Atlantic mackerel 2 0.7 4.1 3 7 7 37 2 9 14 2 958 63 27 1 6 9 0.3 54 7 91 10 2 615 9 12 6.9 6 0.7 4.1 7 2 1.1 59 4 123 22 21599 3515 261 3 10 87 155 106 4 13349 16 156 9.3 5.3 318 3 8 4 208 236 3 634 1 10 9 1 15.2 (2005)159.7 (2001)78.3 (1997)164.4 (1974)266.9 (1998)639.1 (1996)377.6 (1998)573.8 (1998)799.7 (1998)128.0 (1987)37282.0 (1995)8193.2 (1990)355.5 (1998)35.0 (1980)495.9 (1981)224.0 (1992)50.6 (1998)2215.6 (1998)290.6 (2004)2700.0 (1981)813.5 (1998)59.1 (1978)12917.0 (1981)119.0(1981) 840.3 (2007)212.8 (2005)115.8 (1999)301.8 (2009)268.6 (1998)2162.5 (1981)60.1 (1996)9 Normandeau Associates, inc.9 Normandeau Associales, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment MOnitOTMig Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Table 1 (continued).

Densities per 100 m 3 of water: Long-term Mean +Mean' 2 std.dev.Mean +2.58 std.dev.Previous High (Year)August EGGS Searobins Labrids 2 Windowpane 2 LARVE Atlantic menhaden 2 Fourbeard rockling Silver hake Hake Tautog 2 Cunner 2 September EGGS Atlantic menhaden 2 Labrids 2 Windowpane LARVAE Atlantic menhaden 2 Fourbeard rockling Silver hake 2 Hake Tautog 2 Cunner 2 October EGGS Atlantic menhaden 2 Windowpane 2 LARVAE Atlantic menhaden 2 Fourbeard rockling Hake November LARVAE Atlantic menhaden 2 Atlantic herring2 December LARVAE Atlantic herring2 4 23 15 936 136 6 10 4 3.6 6 I 2 3.2 10 5.3 2 4 15 42 2 11 1.6 4 1 5 1 1 112 3 159 42.7 2 2 2 6 9 89.2 (1995)3500.0 (1984)261.3 (2006)760.2 (2008)204.6 (1983)157.3 (2009)235.9 (2008)89.6 (2008)254.0 (1997)73.2 (1993)112.8(1993) 539.6 (2005)81.0 (1999)68.6 (1993)46.2 (1999)327.2 (1997)32.1 (2009)42,1 (1993)163.6 (2002)40.2 (2000)70.3 (1997)67.9 (1994)13.7 (19851 57.1 (1997)124.8 (1995)216_7 (19Q9\2 1 6 2 4 2.3 1 1 0.4 4 16 2 1 8 2 3 21670995)'Geometric or Delta Mean.2 Species of commercial, recreational, or biological interest for which more critical unusual event level will be used.10 Normandeau Associates, Inc.10 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring SECTION IV RESULTS A. Ichthyoplankton Entrained  

-2010 Estimated densities per 100 m 3 of water for each species listed by date, station, and replicate are presented for January-December 2010 in Appendix A (available upon request).

The occurrence of eggs and larvae of each species by month appears in Table 2. lchthyoplankton collections are summarized below within the three primary spawning seasons observed in Cape Cod Bay waters: winter-early spring, late spring-early summer, and late summer-autumn.

Ichthyoplankton entrained during January through April generally represent winter-early spring spawning fishes. Many of these species employ a reproductive strategy that relies on demersal, adhesive eggs not normally entrained.

As a result, more species are typically represented by larvae than by eggs during the early portion of the year. Over both life stages the number of species represented in the catch increased from 6 in January to 16 in April. Egg collections in winter-early spring were numerically dominated by the Gad idae-Glyptocephalus egg group, the Labridae-Limanda egg group, windowpane, fourbeard rockling (Enchelyopus cimbrius), and American plaice eggs. These species accounted for 40, 27, 11, 10, and 8% of the total egg catch during the period, respectively.

Gadidae-Glyptocephalus eggs were entrained from January through April with respective monthly geometric mean densities of 0.4, 0.4, 4.0, and 0.3 eggs per 100 m 3 of water. Labridae-Limanda eggs were entrained in March and April with monthly geometric mean densities of 0.3 and 3.2 eggs per 100 m 3 of water, respectively.

Windowpane eggs were entrained in March and April with corresponding monthly geometric mean densities of 0.1 and 1.5 eggs per 100 m 3 of water. Fourbeard rockling eggs were also entrained in March and April with corresponding monthly geometric mean densities of 0.03 and 1.4 eggs per 100 m 3 of water. Lastly, American plaice eggs were entrained in March and April with monthly geometric mean densities of 0.5 and 0.8 eggs per 100 m 3 of water, respectively.

In the winter-early spring, 16 species of larval fish were collected from the discharge canal. Sand lance, grubby (Myoxocephahis aenaeus), rock gunnel (Pholis gunnellus), and Atlantic seasnail (Liparis atlanticus) made up the majority of the larval fish collected from January to April, contributing respectively, 42, 21, 16, and 5% of the total collected.

Sand lance I1I Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring were collected from January through April with monthly geometric mean densities of 0.04, 1.4, 3.5, and 15.1 larvae per 100 m 3 of water, respectively.

Grubby were collected during February through April with corresponding monthly geometric mean densities of 0.3, 3. 1, and 5.6 larvae per 100 m 3 of water. Rock gunnel were collected from January through April with respective monthly geometric mean densities of 0.4, 2.8, 3.2, and 0.1 larvae per 100 m 3 of water. Atlantic seasnail were collected during April with a monthly geometric mean density of 1.9 larvae per 100 m 3 of water.Winter -Early Spring January -April 2010 Eggs American plaice 7.8%Windowpane 10.7%All others 5.3%Larvae Labridae-Limanda 27.1% Sand lance 42.3%I Fourbeard rockling 9.5%Grubby 20,6%I Rock gunnel 16.2%Atlantic seasnail 5.0%Gadidae-Glyptocephalus 39.6%All others 16.0%Sum of monthly means = 16.50 Sum of monthly means = 51.46 Figure 2: Dominant species of fish eggs and larvae found in PNPS ichthyoplankton samples during the winter-early spring season, 2010. Percent of total and summed monthly mean densities for all species are also shown.Late Spring-Early Summer (May-July)

May through July represents the late spring-early summer ichthyoplankton season, typically the most active reproductive period among temperate fishes. Considering both eggs and larvae, 30 species were represented in the May-July collections, 23 species by eggs and 24 species by larvae. Numerically dominant eggs were the tautog-cunner-yellowtail flounder egg 12 Normandeau Associates, Inc.12 Normandeau Associates, Inc, Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring group (Labridae-Limandaferruginea), the fourspot flounder-windowpane egg group (Paralichthys oblongus-Scophthalmus aquosus), the fourbeard rockling-hake-butterfish egg group (Enchelyopus-Urophycis-Peprilus) and Atlantic mackerel (Figure 3). Tautog-cunner-yellowtail flounder eggs accounted for 85.5% of the late spring-early summer egg catch, and peaked in June at a geometric mean density of 1616.6 eggs per 100 m 3 of water. Labrid egg measurement studies completed at PNPS suggested that the majority of labrid eggs collected near PNPS are cunner (Scherer 1984). Labrid eggs far exceed yellowtail eggs during the period when they are indistinguishable from each other. Fourspot-windowpane eggs accounted for 5.2% of the seasonal egg catch, and peaked in June with a geometric mean density of 74.9 eggs per 100 m 3 of water. Fourbeard rockling-hake-butterfish eggs accounted for 3.6% of the late spring-early summer egg catch, and peaked in June with a geometric mean density of 28.0 eggs per 100 m 3 of water. Atlantic mackerel eggs accounted for 2.7% of the seasonal egg catch and also peaked in June when they were collected at a mean density of 25.0 eggs per 100 m 3 of water.Numerically dominant larvae during late spring-early summer collections were cunner, winter flounder, radiated shanny (Ulvaria subbifurcata), tautog, fourbeard rockling, yellowtail flounder, and Atlantic menhaden (Figure 3). Cunner accounted for 34.8% of the seasonal total, winter flounder for 13.0%, radiated shanny for 10.8%, tautog for 7.3%, fourbeard rockling for 7.0%, yellowtail flounder for 4.9%, and menhaden for 4.9%. Cunner larvae were observed in June and July with monthly geometric mean densities of 1.8 and 31.1 larvae per 100 m 3 of water, respectively.

Winter flounder larvae were collected in May and June with monthly mean densities of 5.8 and 1.5 larvae per 100 m 3 of water. Radiated shanny were observed from May through July with corresponding monthly means of 5.3, 2.3, and 0.3 per 100 m 3 of water. Tautog larvae were collected from May through July with respective monthly mean densities of 0.6, 0.6, and 6.1 per 100 ml of water. Fourbeard rockling were most abundant in June with a monthly mean density of 2.0 per 100 ml of water. Yellowtail flounder larvae were most abundant in May with a monthly mean density of 2.0 per 100 m 3 of water. Lastly, Atlantic menhaden larvae were most abundant in July with a monthly geometric mean density of 3.1 per 100 m 3 of water.13 Norm andeau Associates, Inc.13 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Late Spring -Early Summer Season May -July 2010 Eggs Larvae TautogCunnerYellowtail Winter flounder 85.5% 13.0%Radiated shanny 10,8%Cunner Yellowtail flounder 34.8%4.9%73%All others All others Fourbeard rockling FourspotWindo p e 3.1% 17.3% Atlantic menhaden 7.0%5.2% RocklinggHakeButterfish 4.9%Atlantic mackerel 3.6%2.7%Sum of monthly means = 2989.68 Sum of monthly means = 94.37 Figure 3. Dominant species of fish eggs and larvae found in PNPS ichthyoplankton samples during the late spring-early summer season, 2010. Percent of total and summed monthly mean densities for all species are also shown.Late Summer -Autumn (August -December)This season is typically marked by a decline in both overall ichthyoplankton density and in the number of species collected.

Considering egg and larval stages combined, 27 species were collected during the August through December period; 21 species in August declined to 3 species in December.

Numerically dominant eggs were the tautog-cunner-yellowtail, silver hake-scup-weakfish, fourspot flounder-windowpane, and fourbeard rockling-hake-butterfish egg groups.Seasonal percentages for these egg groups were 34%, 34%, 15%, and 12%, respectively (Figure 4). Tautog-cunner-yellowtail flounder eggs were present in August through October, the highest geometric mean density occurred in August at 28.9 eggs per 100 m 3 of water. Silver hake-scup-weakfish eggs were present from August through October and peaked in August at 19.2 eggs per 100 m 3 of water. Fourspot flounder-windowpane eggs occurred from August through October and peaked in August (13.8 egg per 100 m 3 of water). Lastly, fourbeard rockling-hake-butterfish eggs were collected from August through November and peaked in August (14.2 eggs 14 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring per 100 m 3 of water). Larval dominants in the late summer-autumn season were cunner, tautog, Atlantic menhaden, hake, fourbeard rockling, fourspot flounder, windowpane, and silver hake (Merluccius bilinearis).

Seasonal percentages for these species were 26, 13, 9, 8, 8, 6, 6, and 5%, respectively (Figure 4). Cunner were collected from August through October with corresponding geometric mean densities of 5.0, 0.3, and 0.1 larvae per 100 m 3 of water. Tautog were collected in August through October with geometric mean densities of 1.3, 2.8, and 0.1 larvae per 100 ml of water, respectively.

Atlantic menhaden occurred from August through October at geometric mean densities of 0.4, 1.3, and 0.5 larvae per 100 m 3 of water. Hake were present from August through October at geometric mean densities of 1.8, 0.9, and 0. 1 larvae per 100 m 3 of water. Fourbeard rockling occurred from August through November.

Peak density occurred in August with a geometric mean of 1.7 larvae per 100 M 3.Fourspot flounder were collected from August through October. The peak density occurred in August at 1.1 larvae per 100 m 3 of water. Windowpane were present from August through October and peaked in September at 1. 1 larvae per 100 m 3 of water, respectively.

Lastly, silver hake were observed in August and September, and peaked in August at a mean density of 1.7 larvae per 100 m 3 of water.15 Normandeau Associates.

Inc.15 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Late Summer -Autumn Season August -December 2010 Eggs Larvae Altantic menhaden HakeScupWeakfish Fourspot flounder 9.0% Silver hake Hake 33.7% 6.2% 85.4%FourspotWindowpane 14.8%All othersRocking 5.2% -263%RocklingHakeButterfish 12.0% All others 19.0%TautogCunnerYellowtail Tautog 34.3% 12.5%Windowpane 5.6%Sum of monthly means = 148.89 Sum of monthly means = 35.08 Figure 4. Dominant species offish eggs and larvae found in PNPS ichthyoplankton samples during the late summer-autumn season, 2010. Percent of total and summed monthly mean densities for all species are also shown.B. Unusual Entrainment Values Ichthyoplankton densities reached the unusually high level, as defined under Methods, during the 2010 sampling season on 76 specific occasions and involved fourteen species (Table 3). These species were Atlantic herring, seasnail, winter flounder, radiated shanny, windowpane, Atlantic menhaden, searobins, American plaice, hake, Atlantic mackerel, fourbeard rockling, silver hake, and labrid species. Several species recorded unusually high densities either on several occasions or during more than a single month. In general, unusually high densities were sporadic and of short duration.Atlantic herring larvae reached unusually high entrainment numbers on six occasions in 2010 (Table 3). The March 1 7 th density (6.9 larvae per 100 m 3 of water) exceeded 94% of all previous March densities.

Seasnail larvae occurred at unusually high densities on two occasions in 2010 (Table 3), the April 2 3 rd density (19.7 larvae per 100 in 3) exceeded 95% of all previous April densities.

16 Norinandeau Associates, inc.16 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Radiated shanny larvae were collected at unusually high densities on three occasions in 2010 (Table 3). The April 3 0 th density of 10.3 larvae per 100 m 3 of water exceeded 95% of all previous April densities.

Winter flounder larvae attained an unusually high density once in 2010 on April 2 3 rd (17.8 larvae per 100 m 3 of water) exceeding 95% of all previous April densities (Table 3).Labrid eggs were observed at unusually high densities on four occasions in 2010 (Table 3). The May 31t density (4300.9 eggs per 100 in 3) and the September 1 0 th density (28.6 eggs per 100 in 3) exceeded 97% of all previous May and September densities respectively.

Windowpane eggs reached unusually high entrainment numbers on five occasions in 2010 (Table 3). The May 2 4 th density (458.7 eggs per 100 M 3) and the August 2 0 th density (231.2 eggs per 100 M 3 ) exceeded 99% of all previous May and August values, respectively.

The October 8h density (17.1 eggs per 100 M 3) exceeded 95% of all previous October values.Atlantic menhaden eggs were recorded at unusually high densities on six occasions in 2010 (Table 3). The density of 266.4 eggs per 100 m 3 of water on June 25"h exceeded 98% of all previous June densities.

The July 5 th and 7 th densities (42.4 and 27.0 eggs per 100 m 3 of water)exceeded 99 and 98% respectively of all previous July densities.

Searobin eggs occurred at unusually high entrainment numbers on five occasions in 2010 (Table 3). The June 2 5'h and 30th densities (17.0 and 13.6 eggs per 100 M 3 of water)correspondingly exceeded 99 and 98% of all previous June densities.

The August 2 0 th density of 26.0 eggs per 100 in 3 of water exceeded 98% of all previous August densities.

American plaice eggs were collected at unusually high densities twice in June 2010 (Table 3), with the June 7 th density (19.9 eggs per 100 M 3) exceeding 99% of all previous June densities.

Hake larvae were attained at unusually high entrainment numbers on eight occasions in 2010 (Table 3). The June 4 th density of 2.7 larvae per 100 M 3 of water surpassed 95% of all previous June densities.

Additionally, the larval density collected on July 3 0 th (4.6 larvae per 100 in 3) surpassed 92% of all previous July densities.

Atlantic mackerel eggs reached unusually high densities twice in July 2010 (Table 3).The July 2 nd and 5 th densities (29.1 and 22.4 eggs per 100 M 3 , respectively) exceeded 97and 96%of all previous July densities.

17 Normandeau Associates, Jnc.17 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Atlantic menhaden larvae occurred at unusually high densities three times in 2010 (Table 3). The July 7 h density of 19.4 larvae per 100 m 3 of water exceeded 90% of all previous July densities.

Fourbeard rockling larvae were collected at unusually high numbers on two occasions in 2010 (Table 3). The August 6 Ih larval density (20.8 larvae per 100 M 3) exceeded 95% of all previous August densities.

Tautog larvae were recorded at unusually high densities twenty times in 2010 (Table 3).The July 7 rh larval density (22.6 larvae per 100 M 3) exceeded 96% of all previous July densities.

The larval densities collected on September 81hand 101h (12.6 and 22.2 larvae per 100 M 3 , respectively) each surpassed 99% of all previous September densities.

The September 1 5 th and 22 d larval densities (8.7, and 9.1 larvae per 100 M 3 , respectively) surpassed 96 and 97% of all previous September densities.

Silver hake larvae attained unusually high densities on three occasions in August 2010 (Table 3). Larval densities collected on August 2 0 th, 2 5 th, and 2 7 th (8.2, 7.2, and 12.5 larvae per 100 M 3 respectively) each exceeded 95% of all previous August densities.

Lastly, cunner larvae appeared at unusually high densities four times in 2010 (Table 3).The August 6 th density (118.9 larvae per 100 M 3) surpassed 98% of all previous August densities.

C. Multi-year Ichthyoplankton Comparisons A master species list for ichthyoplankton collected from the PNPS discharge canal for the years 1975 through 2010 is provided in Table 4. A total of 40 species were represented in the 2010 collections, slightly above the 1975-2009 time series mean of 39 species.Appendix B (available upon request) lists geometric mean monthly densities along with 95% confidence limits for each of the numerical dominants collected over the January-December period dating back to 1981. Geometric means are reported because they more accurately reflect the true population mean when the distribution of sample values are skewed to the right as is commonly the case with plankton data. Generally low values obtained for both eggs and larvae during April-June 1984 and 1987, as well as May-June 1999, were shaded because low through-plant water volumes during those months probably affected the measurement of ichthyoplankton densities (MRI 1994). Entrainment data collected from 1975-1980 remain in an outdated computer format requiring conversion before geometric mean densities can be generated.

These 18 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrairanent Monitoring years were therefore excluded from comparison.

To help compare values over the 35-year period, egg data were plotted in Figure 5 for those species whose combined total represented 96% of the 2010 egg catch. For this figure, cod, haddock, pollock and witch flounder eggs were combined in the Gadidae-Glyptocephalus group; rockling, hake and butterfish made up the Enchelyopus-Urophycis-Peprilus group, and labrids and yellowtail flounder were combined in the Labridae-Limanda group. For each category shown, the highest monthly geometric means obtained from 1981 through 2009 were joined by solid lines as were the lowest geometric means, and the area between was shaded, indicating the range of these values. Monthly geometric mean values for 2010 were joined by a solid line. Alongside each plot is a bar graph showing annual abundance indices for each year. These were generated by integrating the area under each 2 annual curve using trapezoidal integration  

.One set of bars was based on geometric monthly means and the other, longer time series, on arithmetic monthly means (1975-2010).

Appendix B and Figure 6 contain corresponding data for the 13 numerically dominant species of fish larvae, those accounting for 83% of the 2010 catch as well as total larvae (all species combined).

As mentioned for eggs, low values obtained for both eggs and larvae during April through August 1984 and 1987 and May-June 1999 were flagged in these figures and omitted from the following discussion.

In many cases densities of fish eggs and larvae vary considerably from year to year. For example, over the 28-year geometric mean time series for Atlantic menhaden eggs, the highest annual abundance index (3,023 in 1993) divided by the lowest (10 in 1992) amounted to 292. In spite of such pronounced variation, no consistent upward or downward trend is apparent over the time series for many species including menhaden and windowpane eggs, sculpin and rock gunnel larvae. Following are noteworthy observations concerning the multi-year time series. Since densities of each ichthyoplankton species rise and fall to zero over the course of each representative occurrence season, interannual comparisons are often conveniently made within monthly periods..Atlantic menhaden 2010 monthly mean egg densities were within the historical range that has been observed from 1981 to 2009, and showed the traditional peaks in egg densities 2 Curve integration results in units of (Numbers x days) per 100 m 3 of water.19 NormandeauAssociates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring in late spring and late summer (Figure 5). The 2010 annual geometric mean abundance index (159) increased compared to the 2007 (98), 2008 (53), and 2009 (6) indices (Figure 5). The 2010 arithmetic mean index (1,104) also increased compare to the 2007 (462)through 2009 (9.6) indices, and is the highest since 1997. Atlantic menhaden eggs were collected at unusually high densities on six occasions in 2010 (See Section B above, Table 3).Gadidae-Glyptocephalus eggs were recorded at a new high in March 2010 at a monthly mean density of 4.04 eggs per lOOm 3 of water (Figure 5). Egg group monthly mean densities showed the traditional seasonal characteristics in 2010 with peaks in early spring and early winter that have been observed from 1981 to 2009 (Figure 5). Atlantic cod eggs were typically collected in low numbers at PNPS during winter months from 1975-1987 (5 per 100 m 3 of water, for example).

Following 1987 they became uncommon particularly during January and February.

The gadidae-Glyptocephalus group showed a significant decline from 1975 to 1993 (p<0.001), based on a nonparametric sign test (Sprent 1989). This is consistent with the downward trend reported for Atlantic cod and witch flounder (Glyptocephalus cynoglossus) stocks for this time period, apparently resulting, at least in part, from overexploitation (NOAA 1998, NEFSC 1998). In 1998, the annual geometric mean index (163) reached the highest value since 1989 (195) and suggested that this decline had ended, at least locally, since the values for 1994 through 1997 (119, 114, 122, and 105, respectively), appeared stable at about two times the low value recorded in 1993 (51). From 2000-2003 the geometric mean indices increased (194, 237, 212, and 483, respectively), then decreased from 2004-2006 (334, 208, and 128, respectively) and increased in 2007 (172). The 2010 geometric mean index (253)increased from 2008 (140) and 2009 (212; Figure 5). Overall an upward trend was apparent in these eggs from 1999 through 2005, which is consistent with increases in the Gulf of Maine Atlantic cod spawning stock biomass from 1998 through 2004. The decline in eggs observed from 2006 through 2008 followed by the increases in 2009 and 2010 may reflect the decline observed in spawning stock biomass in 2005 followed by the increases in 2006 and 2007. The Gulf of Maine Atlantic cod stock is not considered overfished although overfishing is occurring (NEFSC 2008).20 Normandeau Associates, Inc.20 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 20 10 Entrainment Monitoring 0 Rockling, hake, and butterfish (grouped in their early developmental stages, Enchelyopus-Urophycis-Peprilus; MRI 1988) monthly mean egg densities reached a new December high in 2010 at a density of 0.12 eggs per 100m 3 of water, but in general showed the traditional seasonal characteristics observed from 1981 to 2009 in 2010 (Figure 5). Rockling, hake, and butterfish eggs have been uncommon in recent years.Trend analysis using the longer-term arithmetic time series indicated that a significant downward trend occurred from 1978 through 1996 (p = 0.05) even with a moderate catch in 1995. The 1999 (4,715 and 2,366) and 2000 (7,946 and 4,301) indices suggested an upward trend might have begun, however in 2001 arithmetic and geometric mean indices declined (1,897 and 641, respectively).

Although the arithmetic and geometric mean indices improved slightly in 2002 (1,980 and 1,199, respectively), they continued to decline in 2003 (1,915 and 585) and 2004 (953 and 438, respectively).

The 2004 index values were the lowest recorded in the time series. The arithmetic and geometric mean indices increased from 2005 (1,340 and 611, respectively) through 2008 (8,709 and 2,987), and then declined in 2009 (3,019and 1,606, respectively).

The 2010 arithmetic and geometric mean indices increased to 4,298 and 2,377; the geometric mean index was above the 1981-2009 time series average of 2,259 (Figure 5).Fourbeard rockling dominate within this egg grouping based on late-stage eggs as well as larval collections.

Since they are a small bottom fish with little or no commercial value, stock size data are not available with which to compare trends. Hake on the other hand contribute to the commercial bottom fishery. The Gulf of Maine and northern Georges Bank white hake stock is considered to be overfished (NEFSC 2008). The northern red hake stock which includes the Gulf of Maine and northern Georges Bank areas is currently not considered overfished.

The spring and fall total northern red hake stock biomass indices declined from 2003 through 2006 then increased through 2008 (NEFSC 2011). The low egg collections observed at PNPS from 2001 through 2005 followed by an increase through 2008 is consistent with the trend in the northern red hake stock biomass.0 Searobin (Prionotus spp.) egg monthly densities in 2010 showed the traditional late spring -early summer peak that has been observed from 1981 to 2009 (Figure 5).Searobin egg abundance has been low in recent years, a downward trend in egg 21 Norinandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring abundance has occurred during the 1981 through 2010 time period. A Mann-Kendall trend test at a 95% significance level (a = 0.05) using the geometric mean index supports this downward trend (p = 0.003). The 1981-2009 geometric mean abundance index time series shows an alternating, intermittent rise and fall in abundance between years since 1987. The arithmetic and geometric mean abundance indices increased in 1999 (258 and 123) and 2000 (452 and 290), declined in 2001 (108 and 62) and 2002 (57 and 33), and reached a time series low in 2003 of 1.8 and 1.5, respectively.

The arithmetic and geometric mean abundance indices remained low from 2004 (36 and 21, respectively) through 2006 (17 and 8), and then gradually increased from 2007 (39 and 21, respectively) through 2009 (361 and 152). The 2010 indices continued to increase (694 and 319, respectively) and remained above the time series averages of 236 and 146, respectively.

The 2010 indices are the highest values recorded since 1987 (Figure 5).Searobin eggs were recorded at unusually high densities on five occasions in 2010 (See Section B above, Table 3). The Massachusetts Division of Marine Fisheries (MADMF)resource survey trawls showed relatively high searobin abundance during the late 1970's through the mid-1980's followed by a sharp decline through the early 1990's (McBride et al. 1998). The decline in the 1990's appears to be reflected in the PNPS egg data.Labridae-Limanda egg monthly mean densities in 2010 showed the traditional late spring-early summer peak that has been observed from 1981 to 2009 (Figure 5). Labridae (tautog/cunner) eggs, believed to be composed primarily of cunner (Scherer 1984), appeared to be in a downward trend from the late 1970's through 1994 (Figure 5)although a sign test failed to confirm it using the conventional 95% significance level (p= 0.055). The arithmetic and geometric indices both showed an increase in density in 1995. The 1995 arithmetic index appeared exceptionally high and disproportionate to the geometric value due to a single high density in June (37,282 per 100 m 3 of water), which greatly skewed the arithmetic mean for that month. The arithmetic and geometric indices declined in 1997 but increased again in 1998. The 1998 arithmetic index was disproportionately high due to two high densities in June. The geometric indices declined in 1999 and 2000 (29,885 and 28,156 respectively) and increased in 2001 (40,559).

In 2002 both the arithmetic and geometric indices declined (32,754 and 14,709 respectively);

the arithmetic mean was the lowest recorded in the 1975-2009 time series.22 Normandeau Associates.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring The geometric indices increased in 2003 and 2004 (15,438 and 32,693 respectively), however in 2005 both the arithmetic and geometric indices declined (45,602 and 12,707 respectively).

In 2006, the arithmetic index increased (55,672) compared to the 2005 index, however the geometric abundance index (11,534) continued to decline, to the lowest value in the 1981-2010 time series. The arithmetic and geometric indices increased in 2007 (82,258 and 34,322 respectively), declined slightly in 2008 (56,123 and 22,201) and then increased in 2009 (125,164 and 25,288 respectively).

The 2010 arithmetic mean index (121,731) decline slightly and remained below the 1975-2009 time series average (127,440).

The 2010 geometric index (70,236) increased to the highest value since 1989 and was above the 1981-2009 time series average of 40,009 (Figure 5).Labrid eggs were recorded at unusually high densities on four occasions in 2010 (See Section B above, Table 3).The downward trend noted through 1994 was consistent with observations of finfish in the PNPS area as well as impingement collections at the Station (Lawton et al. 1995).Changes in sampling protocols at PNPS have negated the ability to monitor general cunner population trends beyond 1994, which in the past were sampled by gill net, trawl, and diver surveys. Numbers impinged appeared to systematically decline from 1980 through 1992 (annual totals dropped from 1,043 to as low as 28 in 1992), then increased in 1993 (93) and 1995 (346). They remained high in 1996 (332), which appeared to roughly parallel the egg abundance data. The impingement total for 1997 (41) and 1998 (101) represented a substantial drop relative to the preceding two years and appeared out of step with the ichthyoplankton collections.

Cunner impingement dropped in 2002 (59), increased from 2003 (172) to 2005 (716), declined from 2006 (384) to 2008 (247), increased in 2009 (895) which was similar to the ichthyoplankton collections.

Cunner impingement declined in 2010 (535; See Impingement Section), which appears out of step with the increase observed in the ichthyoplankton collections.

Early stage yellowtail flounder eggs are similar to and grouped with the labrids.Yellowtail flounder eggs are believed to account for all eggs of the Labridae-Limanda type collected in April since the labrids are not likely to spawn until May. Yellowtail flounder eggs were relatively abundant in April from 1999 through 2002, abundance then declined from 2003 through 2007, increased in 2008, declined slightly in 2009, and 23 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring increased in 2010. The April geometric mean densities were 2.4 per 100 m 3 in 1999, 4.0 per 100 m 3 in 2001, 1.1 per 100 m 3 in 2003, 0.5 per 100 m 3 in 2005, 0.1 per m 3 in 2007, 1.3 per 100 m 3 in 2008, and 1.2 per 100 m 3 in 2009. The 2010 April yellowtail flounder eggs' geometric mean index was 2.5 per 100 m 3 of water. Spawning stock biomass of Cape Cod -Gulf of Maine yellowtail flounder decreased from 2,633 mt in 1990 to 949 mt in 1998, and then increased to 1,797 mt in 2002. The spawning stock biomass declined to 796 mt in 2005 and then increased to 1,922 mt in 2007. The Cape Cod -Gulf of Maine yellowtail flounder stock is currently considered overfished (NEFSC 2008). The decline seen in yellowtail flounder egg abundance at PNPS from 2003 through 2007 followed by an increase in 2008 reflects the overall trend observed throughout the Cape Cod -Gulf of Maine yellowtail flounder stock.Mackerel egg monthly mean densities in 2010 showed the traditional late spring peak abundance observed from 1981 to 2009 in June (Figure 5). Mackerel eggs typically display a sharp peak in their seasonal abundance curve often with one or two very high densities.

For example, in May 1995 a single density of 19,203 eggs per 100 m 3 was recorded on May 26, dropping to 557 eggs per 100 m 3 on the 2 9 th. The second highest density occurred on June 9 1h that year with 4,754 eggs per 100 M 3.Due to these brief sharp peaks, arithmetic and geometric indices are often quite far apart (Figure 5).Mackerel eggs were more abundant from 1988 to 1998 compared to the 1975 through 1987 period. A sign test using the arithmetic index time series supported this upward trend (p < 0.006). In 1999 and 2001, the numbers decreased significantly to 1,135 and 727, respectively.

These decreases are likely due to the fact that the main seawater pumps were off for extended periods during the month of May both years, the peak season for mackerel eggs. In 2002, the geometric mean index increased to the second highest value in 10 years (11,850) but then declined in 2003 (3,411) and 2004 (661). The geometric mean index value increased slightly in 2005 (676) and then declined in 2006 (451) and 2007 (311), which was the lowest value in the time series. The geometric mean increased in 2008 (1,106) and 2009 (1,906), and then declined in 2010 (1,127;Figure 5). Entrainment of high densities of mackerel eggs during the 1990's was consistent with a dramatic rise in stock biomass attributable to reductions in foreign fishing and low commercial landings by U.S. fishermen (Overholtz 1993, NOAA 1998, 24 Normandeau Associates.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring NEFSC 1998). The northwest Atlantic mackerel spawning stock biomass declined from 1,359,003 mt in 1972 to 96,968 mt in 2008, and recruitment declined from an average of 2.1 billion age 1 fish from 1962-1984 to 566 million age I fish from 1985-2009 (TRAC 2010). The decline in mackerel egg densities observed at PNPS during the last eight years is consistent with the decline in northwest Atlantic mackerel productivity.

0 The Paralichthys-Scophthahnus egg group was recorded at new March high in 2010 at a monthly mean density of 0.07 eggs per 100m 3 of water. The traditional high monthly mean egg densities observed during late spring from 1981 to 2009 were seen in 2010 (Figure 5). Windowpane eggs are predominant within the Paralichthys-Scophthahnus egg group based on larval collections.

The geometric mean indices increased from 1994 (2,216) through 2001 (6,377), declined in 2002 (1,396), increased in 2003 (1,973) and 2004 (2,843), and declined slightly in 2005 (2,074) and 2006 (2,038). In 2007 the geometric mean index increased to 7,294 and then decline to 2,792 in 2008. The geometric mean index increased in 2009 (4,496) and 2010 (5,140), and was above the 1981-2009 time series average of 3,061. The arithmetic mean index increased in 2007 (13,474) compared to the 2006 index (4,300) and then declined in 2008 (6,265). The arithmetic mean index increased in 2009 (7,800) and 2010 (9,000) and continued to be above the 1975-2009 time series average (5,213; Figure 5). Windowopane eggs were recorded at unusually high densities on five occasions in 2010 (See Section B above, Table 3).In general these eggs have not shown wide variations in number, at least compared with other species regularly entrained.

Massachusetts Division of Marine Fisheries spring and fall trawl surveys suggest that stocks gradually increased from 1978 to 1995 but then decreased more or less steadily through 2004. A slight increase seems to have occurred from 2005 to 2007 (Matthew Camisa, MDMF, personal communication).

Over that time series catch did not swing over a very wide range, the low being two fish per tow and the high 14 (average of spring and fall surveys).

The Gulf of Maine-Georges Bank windowpane stock is considered to be overfished (NEFSC 2008).* American plaice monthly mean egg densities in 2010 generally showed the traditional seasonal characteristics that have been observed from 1981 to 2009 (Figure 5). The 25 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring highest geometric mean index value in the 1981-2010 time series occurred in 2004 (450).The index dramatically declined in 2005 (54), increased in 2006 (113) and 2007 (230), and then declined in 2008 (113). The arithmetic mean index followed a similar trend declining from 811 in 2004 to 186 in 2005, increasing to 206 in 2006 and 742 in 2007, and then declining to 296 in 2008. Both the geometric and arithmetic mean indices increased in 2009 (375 and 756, respectively) and then declined in 2010 (113 and 173, respectively) dropping below the time series averages (190 and 414, respectively; Figure 5). American plaice eggs were collected on two occasions at unusually high densities in 2010 (See Section B above, Table 3).Plaice egg abundance at PNPS appears to generally follow trends in adult stock size. Entrainment was low in the mid 1980's when stock size was known to be low (NEFSC 1998, NEFSC 2008), increased from 1987 through 1992, and decreased slightly through 1996 although remained above the low of 1990; then rose again through 2001.Egg abundance has fluctuated from 2002 through 2007. Relatively strong egg production near PNPS may be accounted for by the strong year class produced in 1992 and a reduction in fully recruited fishing mortality from 1992 to 1999 (NEFSC 2001).Spawning stock biomass decreased from 10,648 mt in 2001 to 8,560 mt in 2004 and then increased to 15,569 mt in 2007. The Gulf of Maine -Georges Bank American plaice stock is currently not considered to be overfished although the spawning stock biomass is below the target level (28,600 mt; NEFSC 2008).Total eggs collected in 2010, all species pooled together (Figure 5), showed the characteristic temperate fish late spring-early summer peak observed during the 1981-2009 time series. The total egg geometric mean abundance index declined in 2005 (20,056) and 2006 (17,694), increased in 2007 (49,697), and then declined in 2008 (36,468).

The 2006 index was the lowest in the 1981-2010 time series. The 2005 arithmetic mean index (58,440) was the second lowest value in the 1975-2010 time series. The arithmetic mean index increased in 2006 (70,794) and 2007 (106,760), declined in 2008 (80,640), and then increased in 2009 (145,176) and 2010 (147,058; Figure 5). The 2010 geometric index was above the time series average (75,010) although the arithmetic index remained below the 1981-2009 series average (185,827).

The low indices recorded in 2005 and 26 Normandeau Associoles, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring 2006 may reflect to a large extent the below-average production of fourbeard rockling, cunner, yellowtail flounder, mackerel, and American plaice eggs. The increase recorded in 2010 may reflect above average production of searobins, labrid, and Paralichthys-Scophthalmus eggs.Larvae a Atlantic menhaden larvae monthly mean densities show the traditional seasonal characteristics in 2010 (Figure 6). Menhaden larval abundance was relatively high from 1996-1999, then noticeably dropped during 2000 and 2001, climbed slightly in 2002 and then dropped again in 2003 and 2004. The 2004 annual geometric mean abundance index (10) and arithmetic mean index (12) were the lowest values recorded in the time series. The geometric mean abundance index increased from 2005 (312) through 2008 (819), then declined in 2009 (320) and 2010 (194) dropping below the 1981-2009 time series average of 264. The arithmetic mean abundance index increased in 2005 (1,022)and 2006 (1,374), then declined slightly in 2007 (1,116), and increased in 2008 (4,048).The arithmetic mean index declined in 2009 (719) and 2010 (352) dropping below the 1975-2009 time series average of 606 (Figure 6). Atlantic menhaden larvae were collected in unusually high densities on three occasions in 2010 (See Section B above, Table 3).Atlantic menhaden are coastal migrants that travel in schools that can often be quite dense and are attracted to both intake and discharge currents at industrial facilities.

The great variability in numbers of eggs taken at PNPS probably reflects not only numbers of adults in the surrounding waters but variability in the distance from PNPS at which spawning takes place. Spawning stock biomass increased from 1993 through 1995 (Cadrin and Vaughan 1997), which is consistent with the observed increase in egg and larval densities in 1997 and larval densities alone in 1997-1999.

Currently the stock is believed to be healthy (ASMFC 2010) consistent with the relatively high numbers of larvae entrained during the last six years.* Larval Atlantic herring 2010 monthly mean densities showed the traditional spring and early winter peaks that have been observed from 1981 to 2009 (Figure 6). Peak abundance of Atlantic herring larvae shift somewhat from year to year due to abiotic 27 Normandeau Associates, Inc.

PilgTim Nuclear Power Station Marine Ecology Studies 2010 Entraininent Monitoring factors like water temperature.

For example, the major spawning for Atlantic herring in the Northwest Atlantic traditionally occurs from late August through November (Collette and Klein-MacPhee, 2002), but during unseasonably cold winters this spawning seasonality usually shifts later into December, as seen in 2003. Atlantic herring larvae were collected in unusually high densities on six occasions in 2010 (See Section B above, Table 3).Atlantic herring larval abundance indices have proven valuable in management of herring stocks on Georges Bank, Nantucket Shoals, and in the Northwest Atlantic in general (Smith and Morse 1993). The Gulf of Maine-Georges Bank herring stock complex was seriously depleted by overseas fleets during the 1960's and 1970's to the point where no larval herring were found on Georges Bank for a decade (Anthony and Waring 1980, Smith and Morse 1993, Overholtz and Friedland 2002). The stock has increased more or less steadily since 1986 following reductions in fishing pressure to the point where they are abundant on Nantucket Shoals and in the Gulf of Maine-Georges Bank region. The estimated 2008 stock biomass (652,000 mt) is slightly below the BMsy (670,600 mt) but the stock is not considered overfished (TRAC 2009). Larval collections at PNPS from 1994 through 2002 reflect the general increase in stock size, the geometric mean index for those seven years ranking among the top six. In 2003, however, the geometric mean index (32) fell relative to the 2002 index of 147, and represented a fourteen-year low dating back to 1989. The geometric and arithmetic mean indices increased in 2004 and 2005. The 2006 geometric mean index (148) was very similar to the 2005 index (147), however the 2006 arithmetic mean index (349) decreased compared to the 2005 index (602). In 2007 the geometric mean index declined to 9, representing a 1981-2010 time series low. The 2007 arithmetic mean index also declined to 13, representing the second lowest value in the 1975-2010 time series. The geometric and arithmetic mean indices increased in 2008 (72 and 145, respectively), were similar in 2009 (79 and 146), and increased slightly in 2010 to 93 and 185, respectively (Figure 6).Fourbeard rockling larval monthly mean densities showed the traditional seasonal characteristics in 2010 that have been observed from 1981 to 2009 (Figure 6). Larval densities were unusually high on two occasions in 2010 (See Section B above, Table 3).Fourbeard rockling larvae were relatively abundant in 1998 and 1999 due to the 28 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring unusually high densities recorded in July of those years. The annual geometric mean index dropped sharply in 2000 (50), rebounded in 2001 (607), and then declined in 2002 and 2003. The 2003 geometric mean index (47) was a time series low and under one tenth the series average (479). In 2004, the geometric mean index increased (528)relative to the 2002 and 2003 indices. However, the geometric and arithmetic mean indices declined in 2005 (195 and 536, respectively) and 2006 (162 and 346). The 2007 geometric mean index remained essentially unchanged while the arithmetic mean index increased slightly (363). The geometric and arithmetic mean indices increased in 2008 (225 and 522, respectively) and 2009 (330 and 710). In 2010, both the geometric and arithmetic mean indices declined to 194 and 406 remaining below their respective time series averages of 459 and 1,324 (Figure 6). In spite of these swings in abundance, no consistent trend over the times series is evident. As mentioned above under eggs, the rockling is a small bottom fish with little or no commercial value and stock size data are unavailable with which to compare trends.Larval hake monthly mean densities in 2010 were within the historical range observed from 1981 to 2009 (Figure 6). Larval hake densities were unusually high on eight occasions in 2010 (See Section B above, Table 3). Larval hake abundance has been low since 1999. The arithmetic and geometric mean indices declined to time series lows in 2003 (16 and 9, respectively).

The arithmetic and geometric mean indices increased slightly from 2005 (28 and 15) through 2007 (62 and 37), and then increased more noticeably in 2008 (1,332 and 217) and 2009 (1,549 and 226, respectively).

In 2010 both the arithmetic and geometric mean indices declined (188 and 103 respectively), dropping below their respective time series averages of 789 and 200 (Figure 6). The Northeast Fisheries Center (NEFSC) autumn bottom trawl surveys biomass index suggests that the northern red hake stock biomass gradually increased from the 1970's though 2002, steady declined to 1.16 kg per tow in 2005, and then increased reaching 12.46 kg per tow in 2009. Commercial landings reached a historic low in 2005 of 150 mt. The MADMF fall survey biomass increased from a low of 447 mt in 1987 through the 1990's to a maximum of 3,842 mt in 2000, and then declined from 2002 through 2008. The MADMF fall survey biomass was 1,233 mt in 2009. The northern red hake stock is currently not considered overfished (NEFSC 2011). White hake NEFSC autumn bottom 29 Normandeau Associates.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring trawl survey biomass index declined during the 1990's reaching a near record low in 1999. The biomass then increased from 2000 to 2002 due to the strong 1998 year class and then declined to a very low level (Sosebee 2006). Spawning stock biomass was estimated to be 19,800 mt in 2007 which is below the spawning stock biomass maximum sustainable yield of 56,300 mt. The Georges Bank -Gulf of Maine white hake stock is currently considered as overfished (NEFSC 2008). Time series highs in larval hake abundance at PNPS in 1997 (994) and 1998 (932) may indicate production of strong year classes or simply reflect a localized spawning aggregation.

The low larval hake abundance observed in the 2000 to 2007 indices may reflect the declines in biomass of both red and white hake stocks in the Gulf of Maine.Sculpin larval monthly mean densities followed historical characteristics with an early spring peak in 2010 (Figure 6). Sculpin abundance has remained relatively stable over the 36-year arithmetic mean time series (Figure 6). A slight increasing trend occurred from 1977 through 1988 and a secondary peak was observed in 1997 (arithmetic mean index = 5,058, geometric mean index = 2,249). After dropping in 1998 to 1,086, the geometric mean index increased in 1999 (1,668) and 2000 (1,528) before declining in 2001 (958). The sculpin geometric mean index rebounded in 2002 (2,428) to the third highest value since 1981 and the highest since 1988. The arithmetic mean and geometric mean indices then declined from 2003 to 2005. The arithmetic and geometric mean indices increased in 2006 (3,166 and 1,183) but then declined in 2007 (3,044 and 932)and 2008 (844 and 375). The 2008 geometric mean index was a time series low. The arithmetic and geometric mean indices increased in 2009 (1,949 and 843, respectively) and then declined in 2010 to 513 and 305 remaining below their respective time series averages of 2,446 and 1,266 (Figure 6). The major species within this genus entrained at PNPS is the grubby. Since these fish are small and have no commercial or recreational significance, no stock size data are available with which to compare the larval abundance patterns.Seasnail larvae monthly mean densities showed the traditional seasonal characteristics that have been observed from 1981 to 2009 (Figure 6). Seasnail larvae exceeded unusual density levels twice in 2010 although those values did not produce notably high monthly means (See Section B above, Table 3). Larval seasnail abundance has been low in since 30 Norniandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 20 10 Entrainment Monitoring 1998. The arithmetic and geometric mean indices declined to time series lows of 30 and 27, respectively in 2003. The arithmetic mean index has remained at approximately 40%of the 1975-2009 time series average (579) since 2004, with an average index of 234 from 2004-2009.

The geometric mean index has fluctuated continuously since the low in 2003 ranging from 233 in 2004 to 45 in 2007, and has remained below the 1981-2009 time series average (214) since 2005. The arithmetic and geometric mean indices increased slightly in 2010 to 200 and 92, respectively from 122 and 57 in 2009 (Figure 6). Since these fish typically reach a length of less than 6 inches and have no commercial or recreational significance, no stock size data are available with which to compare the larval abundance patterns.Tautog larval monthly mean densities reached a new September high in 2010 with a density of 2.8 larvae per I 00m 3 of water. However in general, the monthly means densities showed the historical patterns that have been observed from 1981 to 2009 (Figure 6). Tautog larvae exceeded unusual high density levels on nine occasions in September corresponding to the new September high monthly mean density observed.Additionally tautog larvae exceeded unusual high density levels on eleven other occasions in 2010, although those densities did not produce notably high monthly means (See Section B above, Table 3). Larval tautog geometric mean abundance reached a five-year high in 2001 (268), followed by a decline in 2002 (73) and 2003 (64), and an increase in 2004 (172). Abundance decreased in 2005 (132) and 2006 (69), and increased from 2007 (79) through 2009 (722). The 2009 geometric mean index was the second highest value in the time series. The geometric mean index declined in 2010 to 337, but remained well above the 1981-2009 time series average of 174. The arithmetic mean indices show a similar increasing trend in 2008 (679) and 2009 (1,198) compared to the 2006 (189) and 2007 (137) values. The 2009 arithmetic mean index was also the second highest value in the time series. The arithmetic mean index declined in 2010 to 538, but continued to remain above the time series average of 346 (Figure 6). The arithmetic mean index (1975-2010) extends over a longer time period than the geometric mean index and historically shows peaks and ebbs from year to year with no apparent long-term trend. Tautog spawning stock biomass declined from 1982 to 2003 (NEFSC 1998, ASMFC 2006a). Recent data indicate that Massachusetts commercial landings decreased 31 AlormandeauAssociales, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrairunent Monitoring from 1993 to 2001 and recreational landings decreased from 1988-2004 (Stirratt 2002, ASMFC 2006a). Due to limited data, the Massachusetts tautog stock status is uncertain although it does not currently appear to be overfished.

However coastwide tautog are considered overfished (ASMFC 2006a).Cunner larval monthly mean densities in 2010 showed the traditional seasonal characteristics that have been observed from 1981 to 2009. Cunner larvae exceeded unusual density levels on four occasions in 2010 although those values did not produce notably high monthly means (See Section B above, Table 3). No consistent long-term geometric mean index trends are apparent for this species. However, cunner larval abundance was low from 2002 through 2007. The geometric mean index declined from 1,697 in 2000 to 115 in 2003. The index increased slightly in 2004 (373), declined again in 2005 (350) and 2006 (259), and then increased from 2007 (294) to 2009 (1,229). The 2010 geometric mean index declined to 1,181 but remained above the 1981-2009 time series average of 1,020 (Figure 6). Arithmetic mean indices for cunner larvae over the time series (1975-2009) also show no apparent trends in entrainment collections, but rather fluctuate between a few years of relatively high abundance followed by years in which cunner larvae were less common. For instance, in 1981 the arithmetic mean index for cunner was 10,701 but then declined sharply to 437 in 1982 and climbed to 2,067 in 1983. The 2010 arithmetic mean index of 2,200 increased slightly compared to the 2009 index of 2,122 but remained below the 1975-2009 time series average of 2,461 (Figure 6). This general fluctuating pattern is repeated throughout the time series and likely reflects a localized, dynamic recruitment pattern for this temperate wrasse. Current stock size data for cunner are unavailable." Larval radiated shanny monthly densities in 2010 showed the historical characteristics that have been observed from 1981 to 2009 (Figure 6). Radiated shanny larvae occurred at unusually high densities on three occasions in 2010 although those values did not produce notably high monthly means (See Section B above, Table 3). Radiated shanny larval geometric mean abundance rebounded in 2000 (239) following a 12-year low in 1999 (73), and reached a seven year high in 2002 (651). The geometric mean index declined in 2005 (101) ending the 5-year increase in abundance, and remained low in 2006 (113) and 2007 (103). The geometric mean index increased in 2008 (456) and 2009 32 Normandeau Associates.

Pilgfirn Nuclear Power Station Marine Ecology Studies 2010 Entraimnent Monitoring (700) and then declined in 2010 to 274, dropping below the 1981-2009 time series average of 384. The 2010 arithmetic mean index also decreased to 462 which was below the 1975-2009 time series average of 834 (Figure 6). Since this is a small, rather inconspicuous bottom fish, relatively little is known of its habits and data are not available concerning population trends.0 Rock gunnel larval monthly mean densities were collected at a new April low in 2010 with a density of 0.06 larvae per 100m 3 of water. However in general, the monthly means densities showed the traditional patterns observed from 1981 to 2009 (Figure 6).Rock gunnel larvae were collected in above-average numbers from 2000 to 2002 but then declined in 2003 and have since remained relatively low. The 2010 geometric mean index (195) declined compared to the 2009 index (351) and continued to remain below the time series average (933). The arithmetic mean index has also shown a low relative abundance since 2003. The 2010 arithmetic mean index (408) was also below the 1975-2009 arithmetic mean index time series average of 1,725 (Figure 6). Overall, however, there was no obvious or statistically significant trend from 1975 to 2010, although there appeared to be intermittent highs in relative abundance followed by one or two-year declines with the abundance indices generally increasing over the 1981-2002 time period.The appearance of rock gunnel larvae from February through April, the three months when they typically are most abundant, fell below the time series mean for these months from 2003 through 2010 consistent with the overall annual indices. Since the rock gunnel is a small bottom fish with no commercial or recreational value, abundance data are not available with which to compare the entrainment estimates.

* Sand lance larval monthly mean densities reached a new November high in 2010 with a density of 0.08 larvae per 1 00m 3 of water, and generally showed the traditional characteristics that have been observed from 1981 to 2009 (Figure 6). The geometric mean index increased nearly three-fold from 1994-2006 (mean index = 2,791) compared to 1981-1993 (mean index = 1,054) indicating a general increase in abundance that began in 1991 after a period of relatively low sand lance abundance from 1987-1990.

Overall, the geometric mean index peaked in 1996 (6,156) and the arithmetic index peaked in 1994. The sand lance geometric mean index increased from 2004 (1,824) to 2006 (3,195). In 2007 the geometric mean index dropped 94% to 189, becoming the third 33 NormandeauAssociales, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring lowest value in the time series and the lowest value since 1988. The 2007 arithmetic mean index (397) also declined 95% from 2006 (7,998) and was the lowest value since 1989. The geometric mean and arithmetic mean indices increased in 2008 (2,911 and 7,223, respectively) and then declined in 2009 (728 and 1,696) and 2010 (633 and 1,0101) dropping below their respective time series averages of 1,856 and 3,854 (Figure 6).Sand lance play an important role in community ecology since they are a major prey source for a number of finfish species including several of the dominant species discussed above: mackerel, cod, hake, plaice, and yellowtail flounder (Winters 1983).Adult sand lance are also a key prey species in the diet of several baleen whales such as humpback (Megaptera novaeangliae) and finback whales (Balaenoptera physalis) that migrate seasonally to or through Massachusetts and Cape Cod Bays and influence these seasonal migrations (Weinrich et al 1997; Hain et al 1995). Traditionally, other dominant prey sources for humpback whales have been Atlantic herring and Atlantic mackerel.However, as both these prey sources declined in abundance during the late 1970's and early 1980's, humpback whales began targeting sand lance as their main prey source for this region (Kenney et al 1996). Unfortunately, sand lance have little to no commercial or recreational value, and therefore abundance data are unavailable to compare to the entrainment estimates.

Atlantic mackerel larval monthly mean densities in 2010 were within the historical range that has been observed from 1981 to 2009 (Figure 6). Peak larval abundance historically occurs in May and June with time series average geometric means of 0.63 and 8.4 per 100 m 3 of water, respectively.

The 2010 May and June geometric means continued to be below these averages with densities of 0.0 per 100 m 3 of water in May and 0.59 in June.Mackerel larvae, like their eggs discussed above, typically display a sharp peak in their abundance curve often with one or two very high densities.

Due to these brief sharp peaks, arithmetic and geometric indices are often quite far apart (Figure 6). The arithmetic mean index generally increased from 1975 until 1995 and then declined.Peaks in abundance occurred in 1981 (10,030) and 1995 (12,086).

The 2008 arithmetic mean index (39) declined from the 2006 (565) and 2007 (387) values. The arithmetic mean increased slightly in 2009 (68) but then declined in 2010 (37) and continued to be 34 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring below the time series average (1,601). The arithmetic mean index has been below the time series average since 1999. The mackerel larval geometric mean index increased in 2001 (159) from 2000 (131) but then declined in 2002 (70) and 2003 (36). A 5-year high occurred in 2004 when the geometric mean index reached 251, but then declined in 2005 (95). The geometric mean index increased slightly in 2006 (139), declined in 2007 (105)and 2008 (20), and then increased slightly in 2009 (30). In 2010 the geometric mean index decreased to 18, the fourth lowest value in the 1981-20 10 time series, and was well below the 1981-2009 series average of 286 (Figure 6). The northwest Atlantic mackerel spawning stock biomass declined from 1,359,003 mt in 1972 to 96,968 mt in 2008, and recruitment declined from an average of 2.1 billion age 1 fish from 1962-1984 to an average of 566 million age 1 fish from 1985-2009 (TRAC 2010). The decline in mackerel larvae densities observed at PNPS since 1999 is consistent with the current decline in the northwest Atlantic mackerel spawning stock biomass.Winter flounder larvae, a species of considerable recreational and commercial interest and value, are typically among the numerically dominant members of the larval fish community around PNPS in May and the first part of June. Winter flounder larval monthly mean densities generally showed the traditional seasonal patterns that have been observed from 1981 to 2009 (Figure 6) although a single individual was collected in August in 2010. Winter flounder larvae were recorded at an unusually high density of 17.8 larvae per 100 m 3 of water in April 2010 which did not produce a notably high monthly mean (See Section B above, Table 3). The annual geometric mean curve area index reached a high of 2,307 in 2001. This high was followed by a decline in 2002 (575) and 2003 (195), a slight increase in 2004 (539), and then a decline from 2005 (492)through 2007 (172). The geometric mean index increased in 2008 (264) and 2009 (272), then declined in 2010 to 258 and remained below the 1981-2009 time series mean of 481.The arithmetic mean index increased in 2004 (3,047); declined in 2005 (2,009) and 2006 (429); and then increased from 2007 (480) through 2009 (1,422). The arithmetic mean index declined in 2010 (593) and was well below the 1975-2009 time series average of 1,162 (Figure 6). Overall these indices varied without trend over the time series.The Southern New England/Mid-Atlantic winter flounder stock, including offshore Cape Cod, continues to be overfished (NEFSC 2008, Mayo and Terceiro 2005).35 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrain.ment Monitoring The 2002 year class was estimated to be very small at only 4.4 million fish; it was followed by an average size year class (21.6 million) in 2003 (Mayo and Terceiro 2005).The 2006 year class was estimated to be the smallest on record (1981 to 2007) at 3.6 million fish and was followed by a small 2007 year class estimated to be 8.8 million fish The 2007 spawning stock biomass was estimated to be 3,368 mt (NEFSC 2008). The Gulf of Maine winter flounder stock appeared to be doing better than the Southern New England stock; this stock was considered to have been rebuilding since 1995 (NEFSC 2003, Mayo and Terceiro 2005) and was listed as not being overfished (Mayo and Terceiro 2005). However, in the most recent stock assessment a high degree of uncertainty in stock status determination exists although all models suggest that current spawning stock biomass is below the spawning stock biomass maximum sustainable yield value. The Gulf of Maine winter flounder stock is now considered to likely be overfished (NEFSC 2008). See additional information below.The total for all larvae combined in 2010 showed the traditional seasonal patterns that have been observed from 1981 to 2009 (Figure 6). The 2010 total larval arithmetic mean index (8,472) declined compared to the 2008 (24,825) and 2009 (23,411) indices and was well below the 1975-2009 time series average (21,179).

The 2010 geometric mean index (5,521) also declined compared to the 2008 (11,264) and 2009 (11,773) indices and was considerably below the 1981-2009 time series average (11,147; Figure 6).36 Normandeau Associates, Inc.36 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrairunent Monitoring Figure 5. Geometric mean monthly densities per 100 m 3 of water in the PNPS discharge canal for the eight numerically dominant egg species and total eggs, 2010 (bold line). Solid lines encompassing shaded area show high and low values over the 1981-2009 period.Brevoortia tyrannus Labridae-Lirnandas Gadidae-Glyptocephalus Enchelyopus-Urophycis-Peprilus Prionotus spp.Scomber scombrus Paralichtys-Scopthalmus Hippoglossoides platessoides Total eggs To the right are plotted integrated areas under the annual entrainment abundance curves for 1975-2010.

An asterisk above 1984, 1987 and 1999 marks the three years when values may have been low due to low through-plant water volumes from April-August.

An asterisk above 1976 indicates abundance value may be low due to absence of sampling during January -late April; see text for clarification.

The actual value in those cases is printed above the bar.37 Normandeau Associates.

Inc.37 Normandeau Associates.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Brevoortia tyrannus bggs 10 I E8 0.z 7. .z J F M AMJ J A SO0N D Month C0i1.9l/Low q*20I0)1500 ,I 1000 F 2000 67,000 23,232 3,02'3.. .... , ..500 F 0.01 0.001 75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 Year (! Abundance Index based on:.t~n 6Arithnnetic means WmGeornetrk man Gadidae -Glyptocephalus 10 I 0.1 0.01 0.001 2000 1500 500 0 75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 80 02 84 86 88 90 92 94 96 98 00 02 04 06 08 10 Year Index based on, nIrthmrrtic means =Geometric meanj MHg/onth0I Figure 5 (continued), 38 Normandeau Associates.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Enchelyopus  

-Peprilus I-9!0.8 S 1000 100 10 I 0.1 0.01 7 7 7 zk : m : m-. 7 z.At: 4j %..........................."ggs 30 25 20 15 10 F M A M J J A S O N D Month hteiud- 1 :~1,' 11. h/Lmw *210'"'": 75 77 79 81 83 85 87 89 9J 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 O0 02 04 06 08 I0 Year 63 Abundance Index based on: Arithmetic means W~eometrk rncJ Prionotus spp.I 100 10 I 400 L E 0.1 L z-z-z-z Z, *2 z Z, z -z 1 'z 7: Z Z Month.0 1200 1000 800 600 400 200 0.01 0.001 75 77 79 81 83 05 87 89 91 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 00 10 Year 6; Abundance&#xa2; Index based on: " Arithmetic mea., WIOcorntn~ri meatsJ Figure 5 (continued).

39 Normandeau Associates, Inc.39 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Labridae -Limanda Eggs 0000 300 1000E 250 10 z z200'10 -15 L ------- -.50100 -J --7 ~~~75 77 790816385 87 09 91 93 95 9799 01 03 0507 09-1 1 76 780g002 9489688090 92 94 96 9800002 04 D600 10 0.001 3 FM A MJ J A SON D Ya Month AudneIie ae n Mo h Anthmic means MiGeornetric mean)Scomber scombrus L gS 10000 1000 100 L 10 71.- -~- ------5'p~I 0 I 200 1- -15D t00 Ft so ------ ---- -----. -[ ~ --------0, 0.01 0.00)0.1.I rr lail I *75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 YcarAbundance Index based on:&#xfd;Arithrnetic trims _=",.metric cn.J F M A M J J A S 0 N D Month Figure 5 (continued).

40 Normandeau Associates, Inc.40 Normandeau Associates, Inc.

Pilgrim Nuclear POWeT Station Marine Ecology Studies 2010 Entrainment Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Paralichthys  

-Scophthalmus EIgs 1000 100 a S 10 I 0.1 I __I 0,01 0.001 J F M A M J J A S 0 N D Month[lHi h/Low ") 11 19 i1 W53 5 8v Y1 j V)9 9 1 99 U1 I.I U) 07 09 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 Year Abundance Index based 6Arithmetic means =Geonwtori'c Figure 5 (continued).

41 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Total Eggs 10000 10M 900 Z 100 10----------- -------- -----i -.-------------------. --W- --U 4- -------J FM AM J J A SON D Month 400 300 200 100 0.1 0.01 0.001 l3 I I iy 61 6j 63 6O 60 YI YJ V3 Y V U V 1 U. V) VI VY 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 Year Abundance Indecx biased o.n: Arithmetic mecans IGeornetne means)Figure 5 (continued).

42 Normandeau Associales, Inc.42 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Figure 6. Geometric mean monthly densities per 100 m 3 of water in the PNPS discharge canal for the thirteen numerically dominant larval species and total larvae, 2010 (bold line).Solid lines encompassing shaded area show high and low values over the 1981-2009 period.Brevoortia tyrannus Clupea harengus Enchelyopus cimbrius Urophycis species Myoxocephalus species Tautogolabrus adspersus Ulvaria subbifurcata Pholis gunnellus Amnmodytes species Scomber scombrus Liparis species Tautoga onitis Pleuronectes americanus Total larvae To the right are plotted integrated areas under the annual entrainment abundance curves for 1975-2009.

An asterisk above 1984, 1987 and 1999 marks the three years when values may have been low due to low through-plant water volumes from April-August, An asterisk above 1976 indicates abundance value may be low due to absence of sampling during January -late April; see text for clarification.

The actual value in those cases is printed above the bar.43 Normandeau Associates, Inc.43 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Brevoortia tyrannus i0-- -----I F M AMJ J A SON D Month 0.1 0.01 0,001 75 77 79 81 83 8S 87 89 91 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 DO 02 04 06 08 10 YEAR&#xfd;Arit'u'nctliu means mGeornerricmen Clupea harengus Larvae 100 1600 1400 10 z z .z :, z z: z 0- 0 ----- .'I 20 100-0ooo ....86 0 0 ........010 .0.01 2400 00, 7577 79 81 8 70 78 8082 J F M A M i J A S O N D Month 6Ai v/~w 3 85 87 89 91 93 95 97 9901 03 05 07 09 84 86 88 90 92 94 9900 02 04 06 08 10 YEAR Abundace Index based on: ma rithmeri&#xa2; means WGeometric  

44 Normandeau Associates, Inc.44 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Enchelyopus cimbrius Larvae 100 10 E z- ---84 12 61 u 0.1 0.01 0.01 J F M A AM)JJ A SO0N D Month[CIfi k,'Low ;;20I 0 75 77 79 81 83 85 87 09 91 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 00 D2 04 06 08 10 A boundanc c Index ba sd on : 6Arithmence means 0(0*omchic inean Urophycis spp.Larvae~1 10 0.1 7 11-r~ ~ r-a ------- --I.8 I 5 0.01 0.001 I F M A M 1 3 A S 0 N D Month CHi h/Low Z20l0 75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 00 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 Year Abundance Inde~x based on.ArL m nans ,n&#xfd;Figure 6 (continued).

45 Normandeau Associates, Inc.45 Normandeau Associates, Inc, Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Myoxocephalus spp.Larvae z 6z'j Z8 70 828:8 010 C2 0.001 J F M A M J J A S 0 N D Month f_ Abur (=

4 01J&#xfd; Arithrneti 89 91 93 95 97 99 01 03 05 07 09 88 90 92 94 96 98 00 02 04 06 08 10 Year ndance Index bas on: ic -ea- Weome&#xa2;fic me"mj)Liparis spp.La Irvae 2500 800 I0.0 I 7\y4 -- --- --- --2000 1500 J1000 S0o 0.1 0.01 0.001 J FM A MJ J A SON D Month 75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 g0 82 84 86 88190 92 94 96 98 00 02 04 06 08 10 Ycat Abundant:ce Index based on: " 6Arithmeitic me~ans WGcornetri meanj Figure 6 (continued).

46 Normandeau Associates, Inc.46 Normandeau Associates, hic.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Tautoga onitis Latrvac I10 72000 I0 21000_ I~000 00 z 7 0 MA--76 7 80 82 8486 8890929496980004060 I JI F M AMJ J A S O NID Month L AudceIixbudo 0.Hi1/o  

~ oercman Tautogolabrus adspersus-20 1000 100 I.0. I z -z zz zz S.7 E .1i*R----, -,. -- ---15 I I 10 &#xfd;25,901----- ------------*-*-*5 0.01 0.001 0 J F M AMJ JA SO0N D Month~75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 8002 84 86 80 90 92 94 96 98 00 02 04 06 08 1 U YearAbundance Index based on.. &#xfd;Arithmnetic means IGeotnenric Figure 6 (continued).

47 Normandeau Associates, Inc.47 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Ulvaria subbifurcata Larvae 2500 100 10 I--- --- ----- ---------"- ----2000 1500 1000 500 9 0.1 0.01 0.001 75 77 79 01 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 Year Abundance Index basedmon: 6A-rithetntic means WlGcomet'ic mean.)Month (Mivh,0.02010 Pholis gunnellus Larvae IDO .............6 10 57 4:., 0.01 -- -75 77 79 01 83 A ~76 78 80 82 8 0.001 ' r FMAMJ J ASOND Month rt 85 87 89 91 93 95 97 99 01 03 05 07 09 4 86 88 90 92 94 96 98 00 02 04 06 08 10 Year Abundance Index based on: hmetic meana IIGeormetric mean Figure 6 (continued).

48 Normandeau Associates, Inc.48 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Ammodytes spp.100 A8 10.I. ' -m-----I MAMJ J 7S N 7o 7 7-------N 8 8 0.1 0.0I 0.001 75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 0709 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 Year Arithmctic

--ns I~omemr r eap Scomber scombrus Larvae 100 10 112 .0.1 0.01 0.001----------------9 JF M AMJ J ASO0N D Month I S 8 8 6 4 2 12,086 10,030-----1 -I I -I, 848'484! .LU f4ifa= rF .fi LWI 75 77 79 81 83 85 87 89 91 93 95 97 99 01 03 05 07 09 76 78 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 10 YearAbundance Ind"x based on: CAnthmclic means 11110cmerric meajs Figure 6 (continued).

49 Nor~nandeau Associates, Inc.49 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Pleuronectes americanus Larvae

: :: -.6 "_. ..... .... ...1006----- ................75 777 7 83-88 -939 9790 03 -00 F JMAM J0 A OND Year-Arnth ic e I-oma b-rd -- -n-Figure 6 (continued).

50 Nor~nandeau Associates, Inc.50 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Table 2. Species offish eggs (E), larvae (L), and juveniles (J) obtained in ichthyoplankton collections from the Pilgrim Nuclear Power Station discharge canal, January-December 2010*.Species ....._At lantic menhaden Brevoortia tyrannus Atlantic herring Clupea harengus Anchovy Anchoa spp.Bay anchovy A. mitchilli Fourbcard rockling Enche/yopus cimbrius Atlantic cod Gadus morhua Haddock Melanogrammus aeglefinus Silver hake Merluccius bilinearls Atlantic tomcod Microgadus tomcod Pollock Pollachius virens Hake Urophycis spp.Striped cusk-eel Ophidion marginaturn Gooselish Lophius americanus Silvers ides Men idia spp.Northern pipefish Syngnathusfuscus Searobins Prionolus spp.Northern searobin P. carolinus Striped searobin P. evolans Grubby Myoxocephalus aenaeus Longhorn sculpin M. octodecernspinosus Shorthorn sculpin M. scorpius Seasnail Liparis atlanticus Black sea bass Centroprislis striaia Scup Stenotomus chrysops Wrasses Labridae Tautog Tautoga onitis Cunner Tautogolabrus adspersus Radiated shanny Ulvaria subbtfurcata Rock gun nel Pho/isgunnellus Wrymouth Cryptacanthodes maculatus Sand lance Ammodytessp.

Seaboard Goby Gobiosoma ginsburgi Atlantic mackerel Scomber scombrus Butterfish Peprilus triacanthus Srmllmouth flounder Etropus microstomus Windowpane Scophihalmus aquosus Sumner flounder Paralichthys dentatus Fourspot flounder P. oblongus Witch Flounder Glyptocephatus cynoglossus American plaice Hippoglossoides platesso ides W inter flounder Pseudopleuronecles arnericanus Yellowtail flounder Limandaferrugineus Hogchoker Trinectes maculatus Number ofspecies 2010 Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Species FLEL /L L EtL F/L EIL L L UJ L L, t/J L L UJ E E E E EtL F/L F/L E/L L F/ L FJL E/L E FJL E FJL E EIL E EL E E E F/L E E E EtL EL E L F/L F EL /L EL FJL L L L E F/L E FIL EL E/L F/L E/LFL F/iL L L E E E L L L L L L L L L L L E E E FJL F/L L L L L L L EL L L L FLL L L L L L L L L L L L L L L L L E/LE/L FiL E E E E E E E E E F LL FJL E/L E/L E'L EL E'L F/L EIL F/L F/L UL E'L L L L L L L L L L L L L L L L I.J UJ LUJJ L E FIL E E/L E EIL FiL FJ L L it.L E E E E F/L FJL FiL E E L EIL FJL /L FL L FiL J L UJ EIL F)L ItL EtL FIL E/l-E E FLt E E L FiL E t. L Ft L FiL FtL EtL FitL L L F/L FitL F/IL FtL FtL FiL FLt L L 6 6 14 16 20 27 20 21 19 12 4 3 40*Occurrence of species in egg groups was based on spawning season and the presence of larvae in samples.51 Normandeau Associates, Inc.

Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entrainment Monitoring Table 3. Ichthyoplankton densities (number per 100 m 5 of water) for each sampling occasion during months when notably high densities were recorded, January -December, 2010. Densities marked by + were unusually high based on values in Table I. Numbers in the last colum indicate percent of all previous values during the month which were lower.Atlantic Herring Larvae Narch 5 0.0 8 0.0 10 0.0 12 1.8 Is 0.0 17 6.9 + 94 19 4.5 + 91 22 4.1 + 90 24 0.0 26 0.0 29 1.4 31 0.8 Previous high: 30.9 (2005)Notice level: 3.0 Radiated Shanny Larvae April 2 0.0 5 0.0 7 0.0 9 0.0 12 1.1 14 1.8 16 1.8 19 0.0 21 6.8 23 1.3 26 4.4 28 0.7 30 10.3 + 95 Previous high: 83.9(2002)

Notice level: 7.0 Labrd .g s May 3 55.2 5 12.3 7 33.5 10 58.2 12 25.3 14 54.7 17 52.9 19 22.3 21 537.4 24 21.2 26 221.0 28 568.0 31 4300.9 + 97 Previous high: 34,050.0(1974)

Notice level: 3514.0 Seasnall Larvae April 2 0.0 5 0.0 7 0.0 9 0.0 12 1.1 14 1.8 16 1.8 19 14.6 + 91 21 0.0 23 19.7 + 95 26 4.4 28 3.2 30 1.3 Previous high: 98.1 (1974)Notice level: 8.0 Winter Flounder Larvae April 2 0.0 5 0.0 7 0.0 9 0.0 12 0.5 14 0.0 16 1.8 19 9,7 21 0.0 23 17.8 + 95 26 0.0 28 6.5 30 0.0 Previous high: 198.3 (1974)Notice level: 12.0 Windomane Eggs May 3 7.8 5 28.5 7 48.8 10 14.8 12 4.2 14 47.1 17 0.0 19 7.1 21 94.4 24 458.7 + 99 26 96.7 28 111.4 31 160.6 + 95 Previous high: 603.9(2008)

Notice level: 147.0 52 Nor~nandeau Associates, Inc.52 NormandeauAssociates, Inc.

Pilgrim Nuclear POWeT Station Marine Ecology Studies 2010 Entrainment Monitoring Pilgrim Nuclear Power Station Marine Ecology Studies 2010 Entraimnent Monitoring Table 3. Continued.

Atlantic Menhaden Eggs June 2 0.0 4 0.0 7 0.7 9 8.6 II 0.7 14 0.0 16 0.0 18 0.0 21 7.4 23 11.8 25 266.4 + 98 28 13.2 30 124.0 + 96 Previous high: 799.7 (1998)Notice level: 22.0 American Plaice Eggs June 2 1.9 4 10.3 + 98 7 19.9 4 99 9 2.0 II 0.7 14 0.0 16 0.0 18 0.0 21 0.0 23 0.0 25 0.0 28 0.0 30 0.0 Searolin Eggs June 2 0.0 4 0.0 7 0.0 9 1.3 II 2.0 14 0.0 16 0.0 18 0.0 21 1.9 23 1.1 25 17.0 + 99 28 7.9 + 96 30 13.6 + 98 Previous high: 128.0(1987)

Notice level: 3.0 Hake Larvae June 2 0.0 4 2.7 + 95 7 0.0 9 0.0 I1 0.0 14 0.0 16 0.0 18 0.0 21 0.0 23 0.0 25 0.0 28 0.0 30 0.0 Previous high: 35.0(1980)

Notice level: 3.0 Previous high: 50.6(1998)

Notice level: 1.0 Radiated S hanny Larvae June 2 0.5 4 10.8 + 82 7 7.1 9 1.3 I1 5.9 14 1.2 16 1.1 18 1.2 21 0.9 23 0.0 25 1.3 28 19.4 + 89 30 1.0 Atlantic Menhaden Eggs July 2 11.6 + 96 5 42.4 + 99 7 27.0 + 98 9 1.1 12 0.0 14 0.0 16 4.7 + 92 19 0.0 21 0.0 24 0.0 26 0.0 28 0.0 30 0.0 Previous high: 290.6 (2004)Notice level: 10.0 Previous high: 59.1 (1978)Notice level: 4.0 53 Normandeau Associates, Inc.53 NormandeauAssociates, Inc.