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Annual Environ Operating Rept 1979, Vol 1,nonradiological
	ML19322E608
Person / Time
Site:	Crystal River
Issue date:	03/31/1980
From:	; FLORIDA POWER CORP.
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.g ANNUAL ENVIRONMENTAL OPERATING REPORT VOLUME 1 - N0tRADIOLOGICAL 1/1/79 - 12/31/79 CRYSTAL RIVER - UNIT 3 FLORIDA POWER CORPORATION FACILITY OPERATING LICENSE NO. OPR-72 DOCKET NO. 50-302 March, 1980 -

APPROVED BY: Manager Nuclear Support Services ;

,,, f$<f, , Of,f,

, , / 1Y,,s as-i Date: 'I tr !Jo,l'/?o l l

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TABLE OF CONTENTS PAGE I Introduction 1 II Maximum Delta T Across Condenser 3 III Maximum Discharge Temperature 4 IV Chemical 5 V Annual Record of Metabolism of Estuarine Ecosystems 6

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VI Cannunity Structure Study 7 VII Impingement of Finfish and Shellfish 8 VIII Chemical-Industrial Waste Water Treatment System 9 APPENDICES I Community Structure Study II Annual Record of Metabolism of Estuarine Ecosystems i AER-Vol .1 * ( Tbl Cont )DN-62

1. INTRODUCTION The Nonradiological Envi ro mental Moni tori ng Program at Crystal River Unit 3 is designed to determine any significant enviromental effects due to power operation, particularly ur. predicted and catastrophic changes. A preoperational program was designed and performed to serve as a baseline for comparison with operational data. Using this baseline and the plant design parameters, limiting Conditions for Operation were developed. Oper-ation within these LCOs will reduce the plant's effect on the environment to a minimal level . This will be cunfirmed by the Nonradiological Surveil-lance Program. It is recognized that a period of adjustment is expected concurrent with the plant's initial ope ration. Therefore, it may not be possible to draw any conclusions fran the data in this report unless the data is similar to the preoperational data. In that case, the plant did not affect the envirorsnent to the extent that a period of adjustment was experienced and that part of the environment may be assumed to be at its stablilzed level. .

Each of the Nonradiological Limiting Conditions for Operation will be ad-dressed ard evaluated separately. Because of the extent of work required to perform the Nonradiological Surveillance Program, some sections of it were contracted out to consultants. The sections which were divided among consultants are delineated in Table I-1. The reports from these consul-tants are conplete in themselves and are inserted in thi s report as Appendices.

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TABLE l-1 i 1

l Consultant Research ETS Section l University of Florida Productivity and respiration 3.1.1 Dr. H.T. Odun in discharge area Productivity, respiration and 3.1.2 biomass in discharge marsh Oxygen measurements in outer bay 3.1.4.a Oxygen measurements in canals 3.1.4.b Stem counts of marsh grass 3.1.4.e Connell Metcalf and Eddy Diversity and biomass in dis- 3.1.1 charge area Zooplankton samples, outer bay 3.1.4.a Monitor seagrass condition 3.1.4.c Oyster reef quadrat counts 3.1.4.d I -

II. MAXIMUM DELTA T ACROSS CONDENSER At Crystal River Unit 3, the temperature rise across the condenser should not exceed 17.5*F for more than three consecutive hours and should not ex-ceed 21*F (Specification 2.1.1). This is based on design data showi ng that the temperature rise will be 17.5*F at capacity and on the three hours re-quired to clean a condenser section.

The monitoring requirements demand the use of RTDs in the inlet and outlet waterboxes that are monitored and ala rmed by the plant computer. Howeve r ,

if the RTDs or computer is inoperative, local indication on the waterboxes must be used. Duri ng initial power ascension, the condenser ai reached 17.5*F before the plant reached 100% power. Investigations lead to the discovery that the conputer RTDs were in a "hotspot" in the outlet water boxes and thus represent an overly conservative reading of the condenser outlet temperature. On March 31, 1977, the RTDs were declared inoperable and local indications used to determine the condenser aT.

It is desiracle to have the computer loggi ng and ala nai ng the condenser aT instead of doing it manually. Further investigations resulted in finding a position in the discharge pipi ng for a computer RTD that has a relatively flat thermal profile. This modification is being pursued.

The condenser AT limit of 17.5*F was never exceeded for more than three hours and 21*F was never exceeded. Because of constantly changing plant conditions throughout the year, it is inappropriate to attempt a statistic-al evaluation of the condenser AT. In general, though, a condenser aT of about 17*F usi ng local indicators was the average at full power.

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Ill. MAXIMUM DISCHARGE TEMPERAJUE The temperature of the once-through cooli ng water di scha rged from the Crystal River Energy Center to the Gulf of Mexico should not exceed 103*F for more than three consecutive hours and should not exceed 106*F. These limits are based on the aT specification on the Maximum AT Across Conden-ser, on the design condenser AT's for Units 1 and 2, and on an assumed max-imum ambient water temperature of 87'F. (The maximum ambient temperature ever recorded is 92*F and the mean value of the maximum ambient temper-atures recorded for July from 1945 to 1962 is 89.3*F.)

The temperature monitori ng system is a computer-controlled radio link to the sensor bouys. When this system becomes inoperable, the discharge temp-erature is estimated from the flow-weighted average of the condenser dis-charge temperatures or by actual temperature measurement at the Point-of-Di scha rge.

The discharge temperature to the Gulf of Mexico did not exceed 103 F during 1979 for more than three hours and never exceeded 106*F.

A statistical evaluation of the discharge temperatures to the Gulf of Mexico is inappropriate because of the constantly changi ng thennal condi-tions of the three units at Crystal River.

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IV. CHEMICAL Envircrinental Technical Specification 2.3.1 limits the amount and concen-tration of total residual chlorine in the discharge as the result of chlor-ination of the condenser water boxes. This chlorination is designed to inhibit the growth of marine orgarisms in the condensers. Due to the enployment of mechanical means of cleaning the condensers, chlorination was not required during this reporting period.

Envirornnental Technical Specification 2.3.2 prohibits the use of chronates as corrosion inhibitors in the circulating water system. No chromates were used as corrosion inhibitors in the circulating water systen during the period of this report.

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V. ANNUAL RECORD OF METAB0LISM 0F ESTUARINE ECOSYSTEMS- 3 The annual record of metabolism of estua ri ne ecosy',t ems at the Crystal River site as required by Specifications 3.1.1, 3.1.2, and 3.1.4 (see Table I-1) was conducted by the Department of Environmental Engineer-ing Sciences, University of Florida. The data for the quarterly samples is in Appendix II, as well as the analyses and conclusions.

Five Licensee Event Reports (LERs) were submitted to the Commission:

LER 79-021/04L-0 was the result of a difference of more than ~ two standard deviations between the preoperational study and the opera-tional study of the discharge salt marshes for live biomass, dead bio-mass and gross productivity.

LER 79-039/04L-0 was the result of that same difference in the salt marshes for live biomass and dead biomass.

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LER 79-064/04L-0 was the result of that same difference in the salt marshes for live biomass, dead biomass, net productivity and gross productivity.

, LER 79-099/04L-0 was the result of that same difference in the salt marshes for live biomass and dead biomass.

LER 79-114/04L-0 was the result of that same difference in the salt marshes for dead bionass and for bay metabolisra for net productivity.

VI. COVMUNITY STRUCTURE STUDY i The crmnunity structure study at the Crystal River site as requi red by l Speci/ications 3.1.1 and 3.1.4 (see Table I-1) was conducted by Connell, i

Metcalf and Eddy. The data for the quarterly samples is in Appendix I as 1

well as the analyses and conclusions.

One Licensee Event Report (LER) was submitted to the Commission.

LER 79-027/04X-0 was the result of no sample collection due to high tides and severe weather within one quadrant on the reef for the first quarter of 1979, contrary to Environmental Technical Specification 3.1.4.d. Data gen-erated for these oyster reef samples are based on the lesser number of sam-ples.

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VII. IMP!NGEMENT OF FINFISH AND SHELLFISH -3 The impingenent study at the Crystal River site, as required by Specifica-tion 3.1.3, was conducted by the NUS Corporation. A report of the first year's worth of study . data , " Crystal River Unit 3 Impi ngenent Re po r t ,

March 13, 1977 to March 13, 1978," was forwarded to the staff on August 30, 1978.

Upon approval of the impingement report by the staff, the impingment speci-fication may be discontinued, i

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VIII. CHEMICAL /INDUSTRI AL WASTE WATER TREATMENT The monitoring of the Chemical / Industrial Waste Water is performed to de-termine if the waste water is controlled so as to not adversely affect pub-lic health or the natural aquatic environment. All required samples were collected and analyzed for the required parmeters (Table VIII-1 through 5).

Samples were also drawn fram the intake canal directly to the south of the waste water ponds (Table VIII-6) and from the discharge canal north of the ponds (Table VIII-7). The sampling for January was late as reported in Licensing Event Report (LER) 79-013/04L-0. The Minimum Detectable Level (MDL) of each parameter for the samples is in Table VIII-8.

In adaition to the reporting of results, the tables also list the mean, the

+95% confidence boundaries (defined as the mean +1.96 a) and the range of each parameter for each sample location. For the purposes of statistics, all values that were reported as "<MDL" were assumed to be one-half of their MDL. The statistics for the pH values were performed on the values themselves even though pH is the negative logarithm of th.e hydrogen ion concentration.

For 1979, there were two cases where the same parameters was outside the

+95f. confidence limit for a pond and an outside sample location for the same sample period. These were pH for the East Pond and Well No. 4 in May; and nitrate for the East and West Ponds and Well No. 4. Over the reporting period, fourteen parameters of the two ponds were outside the +95% confi-dence boundaries, eighteen parameters for the three wells, and the two ca-nals has eight parameters outside the limit.

In 1976 (preoperational), 1977,1978, and 1979 (operational), the number of parameters exceeding the +95% confidence limits were twenty-four, twenty-six, twenty-one and forty, respectively. Both 1976 and 1977 each had one sample period in which the same parameter exceeded the +9S% confi-dence limit for a well and a pond,1978 had four such sample periods and 1979 had two such sample periods. ,

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TABLE Vill-1 MONTHLY OlEMICAL-INDUSTRIAL WASTE WATER POND ANALYSIS Sample Location No.1 - East Pond Dis solved Nitrate Phosphate Sulfate Iron Copper Zi nc Date Solids (NO3 ) (PO4 ) (504 ) (Fe) (Cu)' (Zn)

Sampled pH (mg/1-TDS) (mg/1-N) (mg/1-P) (mg/1-504 ) (mg/1-Fe) (mg/1-Cu) (mg/1-Zn) 01-23-79 2.7 2,930 0.24 0.85 875 0.76 0.06 0.05 02-12-79 3.0 1,020 0.16 0.05 500 0.48 0.09 0.06 03-13-79 6.7 395 0.07 0.80 175 0.53 0.13 0.02 04-09-79 3.7 1,220 0.21 0.40 725 92 0.28 0.34 05-16-79 10.4 852 0.14 0.45 450 1.51 0.14 (MDL 06-03-79 4.2 1,470 0.40 0.10 500 62 0.87 0.26 07-05-79 3.4 925 0.96 0.10 500 47 0.17 0.04 08-05-79 3.8 810 0.43 0.10 330 0.66 0.03 (MDL 09-06-79 3.85 1,250 2.95 0.40 425 2.32 0.14 0.09 10-03-79 9.6 250 7.8 2.4 10 .47 (MOL 0.07 11-02-79 3.1 10,635 1.19 0.30 1,075 '

34 0.20 0.22 12-04-79 2.84 1,180 0.80 6.5 415 1.30 0.06 0.17 Mean 4.77 1,911 1.28 1.04 498 20.3 0.18 0.11

+95% Con- 9.99 7,454 5.60 4.64 1,063 81.6 0.63 0.33 fidence Ran9e 2.7/10.4 250/10,635 0.07/7.8 0.05/6.5 10/6,075 0.47/92 0.03/0.R7 0.0?/0.34

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m TABLE VIII-2 MONTHLY CHEMICAL-INDUSTRI AL-WASTE WATER POND ANALYSIS Sample location No. 2 - West Pond Dissol ved Nitrate Phosphate Sul fate Iron Copper Zinc Date Solids (NO3 ) (P04 ) (S04 ) (Fe) (Cu) (Zn)

Sampl ed pH (mg/1-TDS) (mg/1-N) (mg/1-P) (mg/1-504 ) (mg/1-Fe) (mg/1-Cu) (mg/1-Zn) 01-23-79 2.7 1, 770 0.49 1.0 800 1.54 0.15 0.09 02-12-79 10.4 810 0.32 .50 425 0.26 0.02 0.01 03-13-79 11.2 520 0.11 0.55 125 0.66 0.08 0.01 04-09-79 6.0 760 <MDL 2.45 500 5.8 0.18 0.06

, 05-16-79 11.4 975 0.68 0.10 425 0.43 0.03 (MDL Z' 3.40 0.54 0.10 06-08-79 4.6 3,568 .<MDL 2.7 7 50 07-05-79 7.1 1,180 4.7 (MDL 525 3.63 0.06 0.03 08-06-79 5.4 4,968 0.64 0.40 700 1.86 0.16 0.06 09-06-79 9.81 1,530 4.3 0.60 <MDL 1.57 0.11 0.05 10-03-79 9.7 245 7.8 2.7 59 3.31 0.01 0.09 11-02-79 3.8 11,480 D.90 0.10 1,125 44 0.22 0.35 12-04-79 2.83 1,130 0.96 5.4 440 1.11 0.1 0.19 Mean 7.08 2,411 1.74 1.38 490 5,63 0.14 0.087

+95*. Con- 13.53 8,612 6.61 4.57 1,132 29.53 0.42 0.2 73 fidence Range 2.7/11.4 254/11,480 0.11/7.8 n.lo/5.4 5.25/1,125 0.26/44 0.01/0.54 0.01/0.15

TABLE VIII-3 MONTHLY OlEMICAL-INDUSTRIAL WASTE WATER POND ANALYSIS Sample Location No. 3 - Well No.1 Dis sol ved Hitrate Phosphate Sulfate Iron Copper Zinc Date Solids (NO3 ) (P04 ) (SO4 ) (Fe) (Cu)- (Zn)

Sampl ed pH (mg/l-TDS) (mg/l-N) (mg/1-P) (mg/1-504 ) (mg/1-Fe) (mg/1-Cu) (m9/1-Zn) 01-23-79 7.5 7,735 0.06 0.25 1,200 1.85 (MDL 0.08 02-12-79 7.3 9,570 0.19 0.25 1,250 1.49 0.03 0.09 03-13-79 7.4 7,28 0 0.07 0.20 1,275 1.48 0.01 0.08 04-09-79 7.6 7,085 0.10 0.20 1,150 4.17 0.01 0.12

, 05-16-79 7.8 7,150 0.13 0.15 1,400 2.26 0.02 0.48 M' 1,125 5.9 0.02 0.06 06-08-79 7.5 7,280 (MDL 0.40 07-05-79 7.6 7,090 0.48 (MDL 1,031 1.77 <MDL 0.08 08-06-79 7.7 5,675 0.10 0.40 825 1.17 0.01 0.01 09-06-79 7.97 5,775 0.20 0.30 1,125 2.47 0.04 0.01 10-03-79 7.7 .5,350 0.15 0.5 1,275 2.03 0.01 0.02 11-02-79 7.6 5,210 V.03 0.60 1,425 ,

2.49 0.01 (MOL 12-04-79 7.73 5,105 0.05 0.20 1,075 20.2 0.02 0.15 Mean 7.62 6,692 0.13 0.29 1,180 3.94 0.016 0.099

+95% Con- 7.97 9,266 0.38 0.61 1,502 14.3 0.037 0.351 fidence Range 7.3/7.97 5105/9570 0.03/0.48 0.15/0.6 825/1425 1.17/20.2 0.01/0.04 0.01/0.48

TABLE VIII-4 MONTHLY OiEMICAL-INDUSTRIAL WASTE WATER POND ANALYSIS Sample Location No. 4 - Well No. 4 Dis sol ved Nitrate Phosphate Sul fate Iron Copper Zinc Date Solids (NO3 ) (PO4 ) (504 ) (Fe) (Cu) (Zn)

Sampl ed pH (mg/1-T05) (m9/1-N) (mg/1-P) (mg/1-504 ) (mg/1-Fe) (mg/1-Cu) (mg/1-Zn) 01-23-79 7.1 6,050 0.20 0.05 4,900 4.63 0.02 0.11 02-1?-79 6.9 6,210 0.08 0.05 4,800 3.45 0.04 0.08 03-13-79 7.1 6,120 0.12 (MDL 5,200 4.08 0.03 0.07 04-09-79 7.2 3,985 <MDL <MDL 28 39 <MDL 0.06 05-16-79 7.7 7, 28 0 0.33 0.15 7,500 4.73 0.04 0.57 I" 06-08-79 6.6 4,525 0.04 0.05 3,400 1.02 0.03 0.13 07-05-79 7.3 4,330 0.11 0.0* 2,900 12.50 <MDL 0.20 08-06-79 7.1 3,800 0.06 0.05 2,660 16.06 0.01 0.01 09-06-79 7.29 4,275 0.06 0.10 2,950 10.85 0.02 0.01 10-03-79 7.2 6,710 0.70 0.1 6,700 3.45 0.03 0.03 11-02-79 6.9 3,925 V.16 (MDL 2,600 14.5 0.01 (MDL 12-04-79 7.05 3,940 0.06 0.01 2,650 46.9 0.01 0.08 Mean 7.12 5,096 0.161 0.057 3,857 13.43 0.021 0.113

+95% Con- 7.64 7,588 0.534 0.14 8 7,875 42.28 0.046 0.416 fidence Range 6.6/7.7 3900/7280 0.02/0.70 0.02/0.15 28/7500 1.02/46.9 0.01/0.04 0.01/0.57

TABLE VIII-5 MONTHLY Q10MICAL-INDUSTRIAL WASTE WATER PONO ANALYSIS Sample Location No. 5 - Well No. 5 Dis sol ved Nit rate Phosphate Sul fate Iron Copper Zinc Date Solids (NO3 ) (P04 ) (504 ) (Fe) (Cu) (Zn)

Sampl ed pH (mg/1-TDS) (mg/1-N) (mg/1-P) (mg/1-SO4 ) (mg/1-Fe) (mg/1-Cu) (mg/1-in) 01-23-79 7.6 3,705 (MDL (MDL 1,000 1.18 (MDL 0.28 02-12-79 7.3 4,3 20 0.02 (MDL 975 6.20 0.01 0.18 03-13-79 7.4 4,565 0.10 <MDL 1,050 3.45 <MDL 0.22 04-09-79 7.3 5,410 <MDL <MDL 925 6.9 (MDL 0.26 05-16-79 8.5 4,68 0 2.00 0.10 1,075 0.31 0.02 1.21 i' 06-08-79 7.3 5,455 2.00 0.10 950 0.15 <MDL 0.19 07-05-79 7.2 6,58 5 0.07 <MDL~ 1,031 0.97 <MDL 0.39 08-06-79 7.4 7,085 0.78 0.05 995 0.47 0.01 0.38 09-05-79 7.43 10,155 <MDL 0.20 1,075 33 0.03 0.21 10-03-79 9.7 12,530 0.16 0.1 1,700 1.44 0.02 0.04

!-02-79 7.0 6,670 ' O.03 0.20 970 . 2.02 0.02 (MDL 12-04-79 7.11 5,040 (MDL 0.1 750 1.64 0.04 0.02 Mean 7.6 6,350 0.43 0.073 1,041 4.81 0.015 0.282

+95% Con- 9.1 11,429 1.93 0.216 1,482 22.74 0.037 0.906 fidence Ra nge 7.0/4.7 3705/12530 0.02/2.00 0.05/0.2 750/1700 0.15/33 0.01/0.04 0.02/1.21

Contami nat ed ,

TAllLE Vill-6 MONTHLY CHEMICAL-INDUSTRI AL WASTE WATER POND ANALYSIS Sample Location No. 6 - Intake Canal Dissolved Nitrate Phosphate Sul fate Iron Copper Zinc Date Solids (NO3 ) (PO4 ) (504 ) (Fe) (Cu) (Zn)

Sampl ed pH (mg/1-TDS) (mg/1-N) (mg/i-P) (mg/1-SO4 ) (mg/1-Fe) (mg/1-Cu) (mg/1-Zn) 01-23-79 8.0 25,700 <MDL 0.15 2 ,0 50 0.19 0.12 (MDL 02-1 '-79 8.2 23,110 <MDL 0.10 1,6 50 0.11 0.05 0.02 03-13-79 8.1 23,010 (MDL <MDL 1 , 70 0 0.27 0.04 (MDL 1,775 * *

04-09-79 8.5 24,740 <MDL 0.17

, 05-16-79 8.2 23,465 0.03 <MDL 1 ,8 50 0.40 0.03 5.5 G' 25,740 0.05 1,800 0.27 0.04 0.01 06-08-79 7.9 <MDL 07-05-79 7.9 28,405 0.12 (MDL 1,875 0.60 0.02 (NDL 08-06-79 8.1 28,485 0.07 0.15 1,7 50 0.50 0.06 0.05 09-06-79 7.85 24,010 (MDL 0.20 1,925 0.20 0.07 0.01 10-03-79 8.0 25,600 <MDL 0.2 2,750 0.62 0.02 0.05 11-02-79 8.1 26,370 0.02 0.10 2,1 50 0.18 0.05 <MDL 12-04-79 6.92 23,630 0.03 0.1 1,900 0.17 0.32 0.05 Mean 7.98 25,189 0.028 0.103 1,931 0.319 0.075 0.52

+95*. Con- 9.72 28,898 0.095 0.247 2,507 0.675 0.243 3.76 fidence Range 6.97/8.5 23010/28485 0.01/0.12 0.01/0.2 1650/2750 0.61/0.62 0.02/0.32 0.01/5.5

Sa:nple discarded

TABLE Vill-7 MONTHLY OlEMICAL-INDUSTRIAL WASTE WATER POND ANALYSIS Sample Location No. 7 - Discharge Canal Dis solved Nitrate Phosphate Sulfate Iron Copper Zinc Date Solids (NO3 ) (P04 ) (504 ) (Fe) (Cu) (Zn)

Sampl ed pH '(mg/1-T?S) (mg/l-N) (mg/1-P) (mg/l-SO4 ) (mg/1-Fe) (mg/1-Cu) (mg/l-Zn) 01-23-79 7.9 25,710 <MDL 0.15 2,050 0.16 0.13 (MOL 02-12-79 8.1 22,700 <MDL 0.10 1,675 0.11 0.05 0.02 03-13-79 8.1 23,090 <MDL <MDL 1,650 0.27 0.03 <MOL 04-09-79 8.4 24,090 <MDL 0.15 1,675 0.62 0.03 0.02 05-16-79 8.3 23,660 0.07 (MDL 1,750 0.17 0.04 0.02 06-08-79 7.8 25,678 <MDL 0.05 1,750 0.30 0.04 <MDL 07-05-79 7.9 28,730 0.08 (MDL 2,000 0.25 0.02 (MOL 08-06-79 8.2 28,495 0.04 0.20 1,750 0.51 0.07 0.03 09-06-79 8.08 24,390 <MDL 0.20 1,975 0.27 0.08 (MDL 10-03-79 8.1 25,500 <MDL 0.1 2,500 0.64 0.02 0.05 11-02-79 8.1 26,925 0.02 0.10 2,200 0.17 0.05 (MDL 12-04-79 7.57 23,660 <MDL 0.1 1,850 0.15 0.10 0.04 l

Maan 8.05 25,219 0.024 0.097 1,902 0.302 0.055 0.018

&95% Con- 8.49 29,143 0.074 0.235 2,404 0.665 0.122 0.048 fidence l

Ra nge 7.8/8.4 22700/28730 0.02/0.08 0.05/0.2 1650/2500 0.11/0.64 0.02/0.13 0.02/0.05

TABLE VIII-8 MINIMUM DETECTABLE LEVELS Parameter MOL pH 0.001 Dissolved Solids 0.7 mg/t Nitrate 0.02 mg/t j

Phosphate 0.01 mg/t Sulfate 3 mg/t Iron 0.01 mg/t Copper 0.01 mg/t .

Zinc 0.01 mg/t I

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APPENDIX I CCNMUNITY STRUCTURE STUDY AER-Voll*(DN-62)

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CRYSTAL RIVER COMMUNITY STRUCTURE STUDY

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FOR FLORIDA POWER CORPORATION ANNUAL REPORT 197';

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l TABLE OF CONTENTS I tem Page No. 'N TABLE OF CONTENTS i LIST OF TABLES v LIST OF FIGURES vii SIMLARY xiii INTRODUCTION I-l Description of Study Region I-2

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Bac kground I-4 MATERIAIS AND METHODS I- 10 Field Operation I-10 Bottom Core Samples I-10 Venturi Samples I-10 Benthic Plant Samples I-ll Seagrass Monitoring I-ll Oyster Reefs I-12 Zooplankton Samples I-13 Environmental Parameters I-13 Laboratory Operation I-14 Quality Control Review I-14 Bottom Core Samples I-15 venturi Samples I-15 Benthic Plant Samples , I-16 Oyster Ree fs I-16 zooplankton Samples I-17 Voucher Collection I-17 RESULTS I-18 General Coments I-18 Statistical Treatment I-40 Comparisons With Pre-Operational Dats I-40 Temperature and Salinity I-42 i

TABLE OF CONTDITS (con't.)

I tem Page No.

Benthic Animals I-45 General Treatment I-45 venturi Suction Samples I-46 Bottom Core Samples I-49 Total Animal Benthos I-62 Annelids I-65 Post-operational Trends: Annelids I-68 Mollus ks I-68 Post-operational Trends: Mollusks I-70 Crustaceans I-71 ,

Post-operational Trends: Crustaceans 'l-72 Other Groups I-74 Post-operational Trends: Other Groups I-75 Post-operational Trends: Benthic Animals I-75 Comparisons With Pre-operational Data: Benthic Animals I-83 Seagrass and Macroalgae I-91 Macroalgae I-91 Seagrasses I-91 Post-operational Trends: Macroalgae I-96 Comparisons With Pre-operational Data: Macrophytes I-96 Seagrass Monitoring I-103 Inside Radials I-103 Outside Transects I-130 Post-operational Trends: Inside Radials I-152 Post-operational Trends: Outside Transects . I-152 ;

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Oyster Reefs I-153 I

Oysters I-153 Oyster Spat I-158 Other Mollusks I-160 Crustaceans I-160 Comparisons With Pre-operational Data: Oyster Reefs I-162 Zooplan kton I-166 Post-operational Trends: Zooplan kton I-174 DISCUSSIONS AND CONCLUSIONS I-179 REFERENCES I-181 l

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TABLE OF CONTENTS (con't.)

w I tem Py e No.

APPENDIX A I-A-1 APPENDIX B Table B-1. Basic statistics for each taxon and wet and dry weights for each major group from bottom core samples of 1979. I-B-1 Table B-2. Basic statistics for each taxon and wet and dry weights for each major group from venturi suction samples of 1979. I-B-46 Table B-3. Diversity and evenness for each benthic and zooplaakten statico for 1979. I-B-89 Table B-4. Basic statistics on taxon abundance and total dry weights of zooplankton samples of 1979. I-B-92 Table B-5. Basic statistics on inside control and discharge radials for 1979. I-B-148 Table B-6. Basic statistics on outside control and discharge transects for 1979. I-B-168 Table B-7. Two sample t-statistics and descriptive related statistics for 1979 samples. I-B-260 1979 control vs discharge temperature and salinity I-B-260 1979 control vs discharge venturi abundance and biomass I-B-268 1979 control vs discharge venturi annelid abundas,ce and biomass I-B-276 1979 control vs discharge venturi mollusk abundance and biomass I-B-284 1979 control vs discharge venturi crustacean abundance and biomass I-B-292 ;

1979 control vs discharge core annelid abundance and biomass I-B-300 1979 control vs discharge oyster reef adult oyster abundance and biomass I-B-308 1979 control vs discharge oyster reef spat abundance and biomass I-B-316 1979 control vs discharge seagrass biomass I-B-324 1979 control vs discharge total macrophyte biomass I-B-328 1979 second quar ter control vs discharge abundance and biomass for zooplankton I-B-332 iii l

TAB 2 OF CDNTENTS (con't.)

Page No.

Item 1979 fourth quarter inside vs outside for each basin zooplankton I-B-333 1979 fourth quarter control vs discharge abundance and biomass for zooplankton I-B-334 1979 night vs day abundance for control and discharge basins zooplankton I-B-336 1979 night vs day annual zooplankton abundance I-B-337 1979 control vs discharge for night and day zooplankton abundance I-B-339 e

l iv

LIST OF TABLES l I tem Pags a No.

Table 1. Taxonomic list and relative occurrence of benthic organisms (excluding organisms found only on oyster reefs) in the vicinity of Florida Power Corporation's Cyrstal River Plant. I-19 Table 2. Taxonomic list and relative occurrence of benthic organisms on oyster reefs in the vicinity of Florida Power l

Corporation's Crystal River Plant. I-32 Table 3. Taxonomic list and relative occurrence of zooplankton in the vicinity of Florida Power Corporation's .

Crystal River Plant. I-34 Table 4. Mean biomass (grams dry weight) m-2 of major benthic groups other than annelids, arthropods, and mollusks in control and discharge basins during different sampling periods of 1979. I-76 t

Table S. Annual mean biomass (g m-2 except zooplankton g m-3)

' for control and discharge basins, 1977,1978 and 1979. I-77 Table 6. Annual mean abundance m-2 (zooplankton m-3}

for control and discharge basins, 1977, 1978 and 1979. I-78 Table 7. Mean biomass (grams dry weight) m-2 of seagrasses (SG) and macroalgae (MA) at discharge (D) and control (C) stations during diff erent sampling periods of 1979. I-92 Table 8. Mean macrophyte biomass (g dry wt.) m-2 by taxon, sampling period and basin for pre-operational and post-operational (1977,1978 and 1979) studies. . I-97 Table 9. Mean diversity by taxon, sampling period and basin for pre-operational, 1977, 1978 and 1979 studies. I-102 Table 10. Mean percent cover of seagrasses m-2 along two inside control radials and three inside discharge radials for the different sampling periods of 1979. I-104 Table llA. Mean percent cover seagrasses m-2 along outside control transects for different sampling periods of 1979. I-131 Table llB. Mean percent cover seagrasses m-2 along outside

' discharge B transects for different sampling periods of 1979. I-132 Table 11C. Mean percent cover seagrasses m-2 clong outside discharge C transects for different sampling periods of 1979. I-133 l

l l

l v

l LIST OF TABLES (con't.)

l ITDI PAGE NO. ;

Table llD. Mean percent cover seagrasses a-2 along outside discharge D transects for different sampling periods of 1979. I-135 Table 12. Annual mean ratio of biomass /shell length for Crassostrea v ireinica. I-156 Table 13A. Major zooplankton groups and mean numbers m-3 for day, night, surface, and mid-depth tows for June 1979 outside stations. I-171 Table 13B. Major zooplankton groups and mean numbers m-3 for _

day, night, surface, and mid-depth tows for December 1979 outside stations. I-172 Table 13C. Major zooplankton groups and mean numbers m-3 for day, night, surface, and mid-depth tows for December 1979 ins *.de stations. 1-173 l

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vi

~

LIST OF TIGURES m

I tem Page No.

Fig. 1. Map of project area showing oyster reef stations and zooplankton stations. I-5 Fig. 2. Map of project area showing inside radials for seagrass mailtoring and benthic sampling stations. I-6 Fig. 3. Map of project area showing outside transects for seagrass monitoring. I-7 Fig. 4. Temperature at inside stations of control and discharge basins. I-43 Fig. 5. Salinity at inside stations of control and discharge basins. I-44 Fig. 6. Percent contribution of annelids, mollusks and crustaceans to total animal abundance in venturi samples (A) and annelids to total animal abundance in core samples (B). I-47 Fig. 7. Total number of taxa of annelids (A), crustaceans (B),

and mollusks (C) at control and discharge stations. I-48 Fig. 8. Mean abundance m-2 of animals collected in ventuti samples in the conttol and discharge basins. I-00 Fig. 9. Mean abundance m-2 of annelids collected in venturi samples in the control and discharge basins. I-51 Fig. 10. Mean abundance m-2 of mollusks collected in venturi samples in the control and discharge basins. I-52 Fig. 11. Mean abundance m-2 of crustaceans collected in' v'enturi samples in the control and discharge basins. I-53 Fig. 12. Mean biomass m-2 of crustaceans (A) and annelids (B) oollected in venturi samples in the control and discharge basins.I-54 l

l Fig. 13. Mean ba omass m-2 of mollusks collected in venturi samples in the co ntrol and discharge basins. I-55 l

Fig. 14. Mean abtndance m-2 of animals collected in bottom

! core samples in th a control and discharge basins. I-56 Fig. 14-1. Mean biomass m-2 of animals collected in bottom core samples in tr a control and discharge basins. I- 57 Fig. 15. Mean abindance m-2 of annelids collected in bottom core samples in the control and discharge basins. I-58 vii 9

LIST OF FIGURES (con t. )

I tem Page No.

, Fig. 15-1. Mean abundance n-2 of mollusks collected in the l bottom core samples in the control and discharge basins. 1-59 Fig. 15-2. Mean abundance m ?F crustaceans collected in bottom core samples in the control and discharge basins. I-60 Fig. 16. Mean biomass a-2 of annelids collected in bottom core samples in the control and discharge basins. I-61 Fig. 17. Species diversity spectra of benthic animals from venturi samples (A) and bottom core samples (B). I-63 Fig. 18. Evenness spectra of benthic animals from venturi samples (A) and bottom core samples (B). I-64 Fig. 19. Mean benthic animal abundance m-2 in venturi and bottom core samples for the quarterly sampling periods of 1977, 1978 and 1979. I-80 Fig. 19-1. Mean benthic animal diversity (H) in venturi and l

I bottom core samples for quarterly sampling periods of 1977, 1978 and 1979. I-81 Fig. 20. Mean benthic animal evenness (e) in venturi and core samples for quarterly sampling periods of 1977, 1978 and 1979. I-82 Fi Overall benthic community biomass (A) and abundance mg.21.(B) from venturi samples for control and discharge basins for pre-operational, 1977, 1978 and 1979 studies. I-84 Fig. 22. Overall salinity (A) and temperature (B) for control and discharge basins for pre-operational, 1977,1978 and 1979 studies. I-86 Fig. 23. Mean abundance m-2 from venturi control samples of the pre-operational study superimposed over two standard I deviations of the comparable mean from the 1979 study. I-87 Fig. 24. Jean abundance m-2 from venturi discharge samples of the pre-operational study superimposed over two standard deviations of the comparable mean from the 1979 study. I-88 l

l Fig. 25. Mean biomass m-2 from venturi control samples of the pre-operational study superimposed over two standard deviations of the comparable mean from the 1979 study. I-89 l

l viii 1

1

LIST OF FIGURES (cont.)

I tes Page No.

Fig. 26. Mean biomass a-2 from venturi discharge samples of the pre-operational study superimposed over two standard deviations of the comparable mean from the 1979 study. I-90 Fig. 27. Mean macrophyte biomass m-2 in the discharge and control basins. I-94 Fig. 28. Mean leaf length for the seagrass Halodule in the control and discharge basins (A) and for the seagrasses Ruppia, Halophila and Syringodium in the control basin. I-95 Fig. 28-1. Mean macrophyte biomass m-2 for total macrophytes (A), total seagrasses (B), and total macroalgae (C) for quarterly sampling periods of the prp-operational, 1977, 1978 and 1979 studies. I-99 Fig. 29. Percent contribution of seagrass and macroalgae to total macrophyte biomass in the control basin (A) and the discharge basin (B). I-101 Fig. 30. Distribution of Halophila engelmannii along inside radials of the control basin for March 1979. I-105 Fig. 31. Distribution of Ruppia maritima along inside radials of the control basin for March 1979. I-106 Fig. 32. Distribution of Syringodium filiforme along inside radials of the control basin for March 1979. I-107 Fig. 33. Distribution of Halodule beaudettei along inside radials of the control basin for March 1979. ,

I-108 Pig. 34. Distribution of Thalassia testudinum along inside radials of the control basin for March 1979. I-109 Fig. 35. Distribution of all seagrasses along inside radials of the control basin for March 1979. I-110 Fig. 36. Distribution of Halophila engelmannii along inside radials of the control basin for June 1979. I-lli Fig. 37. Distribution of Ruppia maritima along inside radials of the control basin for June 1979. I-112 Fig. 38i Distribution of Syringodium filiforme along inside radials of the control basin for June 1979. I-113 ix

LIST OF FIGURES (cont.)

Item Page No.

Fig. 39. Distribution of Halodule beaudettei along inside radials of the control basin for June 1979. I-114 Fig. 40. Distribution of all seagrasses along inside '.adials of the control basin for June 1979. I - 1 15 Fig. 41. Distribution of Ruppia maritima along inside radials of the control basin for September 1979. I-116 Fig. 42. Distribution of Syringodium filiforme along inside radials of the control basin for September 1979. I-ll7 Fig. 43. Distribution of Halodule beaudettei_ along inside radials of the control basin for September 1979. I-118 Fig. 44. Distribution of all seagrasses along inside radials of the control basin for September 1979. I-119 Fig. 45. Distribution of Halophila engelmannii along inside radials of the control basin for December 1979. I-120 Fig. 46. Distribution of Ruppia maritima along inside radials of the control basin for December 1979. I-121 Fig. 47. Distribution of Syringodium filiforme along inside radials of the control basin for December 1979. I-122 Fig. 48. Distribution of Halodule beaudettei along inside radials of the control basin for December 1979. I-123 Fig. 49. Distribution of all seagrasses along inside radials*

of the control basin for December 1979. I-124 Fig. 50. Distribution of Halodule beaudettei along inside radials of the discharge basin for March 1979. I-126 Fig. 51. Distribution of Halodule beaudettei along inside radials of the discharge basin for June 1979. I-127 f

Fig. 52. Distribution of Halodule beaudettei along inside radials of the discharge basin for September 1979. I-128 Fig. 53. Distribution of ,Halodule beaudettei along inside !

radials of the discharge basin for December 1979. I-129 Fig. 54. Distribution of Halophila engelmannii along outside j transects of the control and discharge areas for March 1979. I-137 x

LIST OF FIGURES (con t. ) ,

I tem Page No.

Fig. 55. Distribution of Syringodium filiforme along outside 1

transects of the control and discharge areas for March 1979. I-138 Fig. 56. Distribution of Halodule beaudettei along outside transects of the control and discharge areas for March 1979. I-139 Fig. 57. Distribution of all seagrasses along outside transects of the control and discharge areas for March 1979. I-140 Fig. 58. Distribution of Halophila engelmannii along outside transects of the control and discharge areas for June 1979. I-141 Fig. 59. Distribution of Syringodiu3 filiforme along outside transects of the control and discharge areas for June 1979. I-142 Fig. 60. Distribution of Halodule beaudettei along outside transects of the control and discharge areas for June 1979. I-143 Fig. 61. Distribution of all seagrasses along outside transects of the control and discharge areas for June 1979. I-144 Fig. 62. Distribution of Syringodium filiforme along cutside transects of the control and discharge areas for Septemaer 1979. I-145 Fig. 63. Distribution of Halodule beaudettei along outside transects of the control and discharge areas for September 1979. I-146 Fig. 64. Distribution of all seagrasses along outside transects of the control and discharge areas for September 1979. I-147 Fig. 65. Distribution of Halophila engelmannii along outside transects of the control and discharge areas for December 1979. I-148 Fig. 66. Distribution of Syringodium filiforme along outside transects of the control and discharge areas for December 1979. I-149 Fig. 67. Distribution of Haledule beaudettei along outside transects of the control and discharge areas for December 1979. I-150 Fig. 68. Distribution of all seagrasses along outside transects of the control and discharge areas for December 1979. I-151 Fig. 69. Ratio of mean biomass (adjusted to constant sample size of 230 oysters) to mean shell length of oysters greater than 2 cm in length at control and discharge oyster reef

( stations. I-154 l

l.

x1

LIST OF FIGURES (con t. )

Item Page No.

Fig. 70. Mean biomass m-2 (A) and mean abundance m-2 (B) of oysters greater than 2 cm at control and discharge oyster reef stations. I-157 Fig. 71. Mean biomass a-2 (A) and mean abundance m-2 (B) of oyster spat at control and discharge oyster reef stations. I-159 Fig. 72. Mean biomass m-2 (A) and mean abundance m-2 (B) for other mollusks at control and discharge oyster reef stations. I-161 Fig. 73. Comparative oyster reef data (adults) for pre-opera tional, 1977, 1978 and 1979 ctudies for summer and winter sampling periods. I-163 Fig. 74. Comparative oyster reef data (spats) for pre-ope ra tional, 1977, 1978 and 1979 studies for summer and winter sampling periods. I-164 Fig. 75. Mean zooplankton abundance (A) and biomass (B) m-3 in the control and discharge basins. I-168 Fig. 76. Percent contribution to abundance in zooplankton samples: contribution of calanoid copepods, molluscan veligers, harpacticoid copepods and decapod larvae to total zooplankton abundance (A); contribution of taxa of secondary numeric importance to the remainder category of "A" (B) ; contribution of Acartia tonsa, Pseudodiaptomus coronatus and Paracalanus crassirostris to total calanoid abundance (C). I-170 Fig. 77. Mean zooplankton abundance (A) and biomass.(B) m 3 at control and discharge stations during 1977, 1978 and 1979. I-175 Fig. 78. Total zooplankton diversity (A) and evenness (B) at control and discharge stations during 1977, 1978 and 1979. I-176 Fig. 79.- Percent contribution to total zooplankton abundance during 1977, 1978 and 1979: contribution of major taxa to abundance (A) and contribution of Acartia tonsa to total abundance (B). 1-177 1

l xii

SUMMARY

s The 1979 Final Report presents the results of the post-operational ecological studies for Florida Power Corporation's Crystal River Power Plant.

Benthic samples were collected during March, June, September and December 1979, and zooplankton samples were collected during June and December 1979.

The benthic samples were taken from two inshore basins separated by a long jetty. The northern basin is the discharge area of the thermal effluent from the Crystal River Plant, while the southern basin is the control area.

Zooplankton samples were taken several kilometers seaward of the respective basins. In December 1979, two new inside zooplankton stations were establishea. Seagrass monitoring, encompassing extensive transects seaward of both inshore basins, intitiated in June 1978, was continued through the 1979 sampling year.

Crystal River Unit 3 was shut down on 23 April 1979 and did not resume full operation until 1 August 1979. Results f rom this year 's study probably reflect the absence of thermal effluent from this unit during the shutdown period. During 1978, Crystal River Unit 3 was shut down from 3 March until 29 Sep tember. Crystal River Unit 3 did not commence operations until March 1977. Thus, over the three years of this study, no single year's data reflect an entire year of continuous plant operation.

At this point in the overall post-operational studies, . there seem to be some clearly defined trends being established. No doubt due primarily to xiii

physical differences between basins including substrate types, current patterns, and, perhaps, power plant operations over the past 14 years, the control basin is seen to have a more diverse benthic community than the discharge basin. There are more taxa present in the control basin than in the discharge basin, and, where there are species conson to both basins, they are generally more widely distributed in the control area. This is not surprising since the control basin represents a non-homogeneous habitat.

The control basin is more productive (i.e, shows generally higher biomass), and has greater abundance. The discharge basin appears to becoming more stable and less diverse over time. The fact that there is now a virtual seagrass monoculture present in the discharge basin indicates this pointedly.

It might be significant that the control basin showed an absence of Ruppia and Halophila late in this year's study. Perhaps the study area is becoming less f avorable to a diverse seagrass population; perhaps the absence of these two seagrass species is simply a random or cyclic event.

Zooplankton show somewhat atypical patterns from other community taxa.

Sample variability caused by patchy zooplankton distribution patterns makes analysis of the data difficult, however, and close scrutiny of the data will wa it intil an additional years' data are collected.

I It is not possible to attribute any specific portion of the differences between the discharge basin and the control basin, to the effects of Unit 3 l

operation because the control and discharge basins were already quite different physical and biological systems before the commencement of Unit 3 X iv

operation. These differences, recorded at the outset of the 1977 study, were

's probably due to the combined effects of separation of the two basins by jetty construction, cutting and redirecting of tidal creeks, and the long term operation of the two fossil fuel smits. Hopefully, additional new data and comprehensive analysis of existing data will lead to insight to the effects of power plant operation on the benthic and zooplanktonic communities.

l i

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i e

l XV

INTRODUCTION The purpose of this study is to determine the condition of the benthic and scoplanktonic consnmities in the area potentially affected by the thermal plume from the Crystal River power generating plant. The sampling program was designed to yield data that would detect significant changes which might occur due to the operation of Crystal River Unit 3. The study was initiated in April 1977.

The 1977 and 1978 Final Reports were submitted to Florida Power Corporation; each presented results obtained during the four quarterly sampling periods of 1977 or 1978 and comparisons of the 1977 and 1978 results with those obtained in the pre-operational studies. The following 1979 Final Report includes data from the four quarterly sampling periods of 1979 (March, June, September and December) and compares the 1979 results with those obtained in both the pre-operational studies and the 1977 and 1978 studies.

Direct comparisons with pre-operational data have, of course, been limited to those data for which sampling areas and procedures were essentially the same for pre-operational and post-operational studies. Direct c mparisons and freqpent references are made between the post-operational studies because sampling stations, procedures, and analyses have been virtually identical for f all three years. In addition, possible trends observed during the three years I

of post-operational monitoring are presented and discussed where appropriate.

l l

l I-l

gscription of Study Region The study region is located 105-120 kilometers north of Tampa, Florida (from lat. 28 54'N, long. 82 41'W to lat. 29 02'N, long. 82 45'W) .

The region includes coastal marsh and the waters of the Gulf of Mexico up to 6.5 kilometers from shore. Two rivers discharge their waters into this area, the Crystal River near the southern end, and the Withlacoochee near the

~

northern end. The former has an average flow of 1018 m min and the latter 3092 m min ~l (Grimes,1971) . The Cross Florida Barge Canal,1.5 kilometers south of the main channel of the Withlacoochee River, also contributes freshwater to the system when Inglis Lock (eleven kilometers inland on Lake Rousseau) is opened to allow drainage of storm waters into the cana l. The coastline is dominated by tidal marshes typical of the northwest coast of the Florida peninsula and is characterized by a broad band of Juncus roemarianus fringed on the seaward side by Spartina alterniflora.

The Crystal River Power Pltnt is situated on the shore ,at the approximate middle of the study region; two canals have been dug to serve the facility.

The south canal serves as the intake for cooling water and as a deep water channel for the coal and oil barges that supply fuel to the p!' at. Associated with this canal are spoil jetties on its north and south banks which extend 11.3 and 3.7 kilometers, respectively, from shore. Several breaks in the l

l northern jetty allow for passage of boats. The north (ef fluent) canal carries heated water from the power plant into the Gulf. A 2.0 kilometer-long spoil jetty along the southern border of the effluent canal creates a small embayment between the jetty systems of the effluent and intake canals.

I-2 .

l l The offshore environment is characterized by a series of long, discontinuous oyster reefs, oriented in a roughly north-south direction.

According to Dawson (1955), the tops of many of these reefs are " exposed except during periods of spring high tides, and the tops of the individual segments usually consist of dead shell." From our experience, however, oyster i reefs in this area are covered during normal high tides. Nevertheless, areas of most active oyster growth are on the flanks of the reefs. The substrate is composed of mud over rock near shore, and mixtures of mud, sand and shell of various depths overlaying rock between the reefs.

A series of spoil islands oriented in an approximate east-west chain 4 kilometers north of the plant jetty system extends into the Gulf along the southern edge of the dredged channel of the Cross Florida Barge Canal. The area enclosed by the Barge Canal spoil islands to the north and the power plant's jetty system to the south (henceforth known as the discharge area) appears (FPC, 1978, 1979) to have been changed significantly by some combination of effects from these man-made features. In the only major study conducted prior to the construction of the canals, jetties and spoil islands, Dawson (1955) obtained samples from the general study' area but did not emphasize differences between the substrate within the limits of the present discharge area and those in surrounding localities. The substrate in approximately the first four kilometers from shore in the discharge basin is now a consistent, and of ten deep ( 15 cm) mud over rock, as opposed to the sand, shell and mud mixtures over rock typical of the control areas. Mud deposits within the discharge basin may be attributable at least in part to changes in current l

I-3 l '

l

patterns due to jetty construction. _

The study area is shown in Fig. 1. Also shown in Fig.1 are the sampling stations at six discharge oyster reefs and three control oyster reefs located in th,e inner basins and the two outside zooplankton stations located about four kilometers distant from the respective basins. In December 1979 two inside zooplankton stations were added to the monitoring program (Fig.1). l i

Benthic sampling stations are shown in Fig. 2. These include seven discharge stations anf five control stations. Three discharge and t o control inside radials also are shown which are paths along which the condition and percent cover of seagrasses are nonitored. The seagrass moriitoring transects for the outside areas are shown in Fig. 3.

Background

Literature for the Crystal Bay area is very scant prior to 1971. A study by Dawson (1955) desc:ibed the Crystal Bay region from Mangrove Point (located just south of the study region) to Drum Island (located within the discharge area) as an area with a sand, mud, and broken oyster shell bottom, except for backswamp areas where a deep mud bottom predominated. With a few exceptions the area was very s5 allow with rumerous oyster bars paralleling the shoreline. The average salinity was 16 parts per thousand (0/00). Currents from the Crystal River apparently flowed in a northerly direction along the shoreline past Negro Island and visibility of ten exceeded five feet. A study by Phillips (1961) on the ecology of marine plants of Crystal Bay was more limited in range than Dawson's, being restricted to that area of the bay I-4 i

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I-7 J

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immediately south of the Crystal River. However, for that area, Phillips' s

physical description agrees with Dawson's.

Several events have taken place since Dawson's and Phillips' studies which have had an impact on the study area. There are presently three electrical generating units in operation at the Crystal River Power Plant. Unit 1, a fossil f uel generator, began operation in July 1966. In November 1969, Unit 2, another fossil fuel generator became operational and Unit 3, a nuclear generator, began operating in March of 1977. The intake and ef fluent canals and associated jetty systems were constructed just prior to completion of Unit

1. In ad3ition, construction of the Cross Florida Barge Canal channel and its associated spoil islands was completed in 1967. Since the completion of these activities several studies have been conducted to determine the effects of power plant operation.

A study on the ecological eff ects of the thermal discharge from the Crystal River Power Plant was conducted by the Florida Department of Natural Resources in 1969 and 1970. Some of the results of this study are discussed below. Grimer (1971) described the substrate in the area west of the power plant as varying from hard sand to rock covered with mud near the shoreline, with silt occurring in many areas 4here dredging had taken place. Grimes and Mountain (1972) noted the formation of an inverse thermal stratification in the discharge basin along with a suppressed summer diversity and high winter diversity for fishes occurring within the discharge area. In addition, diversity increased with distance from the Barge Canal in the direction of the intake jetties. 'It was suggested that increased diversity was celated to I-8

salinity, which also increased toward the intake jetties, or habitat de=truction associated with dredging operations, which was greatest in the vicinity of the Barge Canal, or both.

Mountain (1971) noted higher trace metal levels in oysters from the discharge area compared to those in the intake area. Lyons et al. (1971) believed the distribution of invertebrates to be related more to salinity and the presence of the spoil islands and jetties than to temperature. Steidinger and Van Breedveld (1971) found a reduction in marine algae throughout the 4

entire discharge and intake areas between February 1969 and December 1970 and suggested this might be due to siltation from dredging activity rather than increased temperatures.

A baseline study by the Systems Ecology group of the University of Florida was conducted from 1972 through 1974. The results of this study are presented in Crystal River Power Plant: Environmental Considerations Vol I-IV (FPC, 1974). The primary application of this study was to provide pre-operational data in anticipation of the start up of Unit 3.

In 1977, a post-operational benthic study was initiated to determine if the operation of Unit 3 has an impact on the benthic environment. This is an ongoing study conducted by Connell Metcalf & Eddy for which the first two annual reports have been published to date (FPC, 1978, 1979).

l l

I-9

MATERIALS AND METICDS s

Field Operation Bottom Core Samples To collect the smaller macroinvertebrates, a 10 cm (diameter) x 15 cm (deep) aluminum core sampling device equipped with a top vent is us6d. The diver opens the vent and works the device into the substrate by twisting the

~

handles. When the core reaches a depth of 15 cm (or solid rock in some ins tances) , the vent is closed before retrieval. The resulting suction helps retain the sample and minimize loss. The cap is then secured over the open end of the coring device to prevent sample loss. At the boat the sample is washed through a 0.5 mm sieve. The washed sample is put into a labeled container and preserved in 10% buffered formalin in seawater. Rose Bengal (100 mg/1) is added on shore (Mason and Yevich,1967) . Five replicate samples are taken at each benthic station (see Fig. 2).

Venturi Samples The larger macroinvertebrates are collected using a venturi suction pump consisting of two Gorman Rupp 16 horsepower pumps connected in parallel, each operating at approximately 80 psi. A three-inch intake hose on each pump is ,

reduced to a 2 1/2 inch (6.4 cm) outlet hose. These non-collapsible hoses are connected to a diver-operated venturi suction nozzle with the out:r.

l l

I-10 l

i restricted through four backward-thrusting 3/4 inch (1.9 cm) copper pipes.

The nozzle is a four-inch diameter PVC pipe and the outlet is a rigid six-inch diameter hose to which is fitted a 1/8 inch (0.3 cm) mesh nylon bag for retaining the sample.

A one square meter aluminum box (0.6m deep), used to define the sample area, is randomly placed on the bottom and worked into the substrate. A diver directs the nozzle towards the substrate, which is drawn into the col ~1ecting b ag . The sample is taken to a depth of 20 cm where possible. Samples are transferred from the collecting bags to 5 gallon plastic' buckets and preserved in a 104 buffered formalin in seawater solution, to which Rose Bengal (100 mg/1) is added. One sample is taken at each benthic sampling station shown in Fig. 2.

Benthic Plant Sample _s A 0.25 m aluminum box is placed on the bottom by random casts. Divers collect all grasses and macroalgae within the box, including all roots, rhizomes, and holdfasts. Samples are placed in labeled containers and preserved in 10% buffered formalin in seawater. Three replicate samples are taken at each benthic sampling station shown in Fig. 2.

Sea Grass Monitoring Thf a monitoring program assesses the composition and general condition of macrophytes in the discharge.and control areas. Two sets of transects are l

i I-11 i

l

1 monitored in each area. The inside radials (two control and three discharge, 3 Fig. 2), located in the general proximity of the benthic sampling stations, are monitored at 0.1 km intervals. The outside transects, (six control and 17 discharge, Fig. 3) ranging up to 8 kilometers from shore, are monitored at approximately 0.5 km intervals. Weighted PVC frames, used to delineate 1 m quadrats, are randomly placed on the bottom at each monitoring location.

Divers estimate the percent cover, as well as the general growth condition, of seagrasses, the presence of macroalgae (by genus), and the presence and abundance of epiphytes within each quadrat. Five replicate quadrats are analyzed at each monitoring location.

Oyster Reefs At low tide on the exposed oyster reef, a 9 m rope with a mar k at 4.5 m is stretched from the edge of the tidal wash at one end of the reef to the 9 m point midway between the lateral margins of the exposed reef. An aluminum 0.25 m box is placed at the 4.5 m and 9 m points. The perimeters of the sample quadrats are marked and sll material within the quadrats to a depth of at least 10 cm is removed, placed into marked gallon jars, and preserved in 10% buffered formalin in seawater. Rose Bengal is added on shore. The two samples from each reef are randomly selected because their location is determined by the exact position of tidal incursion over the ends of the reef at the time of collection.

I-12 i

l l

l Zooplan kton Samples

! Zooplankton populations are sampled with a 0.5 m, 202 y a mesh net, with a l General Oceanics digital flow meter positioned slightly off center across the i

net south. A second flow meter on a separately towed hoop is used for comparisons of the flow meter readings to estimate the percent clogging of the net. The net and the separate meter are towed for two minutes at approximately two knots. Flow meter readings are recorded before and after the tow. The sample is washed down the net into the attached collecting bottle which then is labeled and preserved in 10% buffered formalin in seawater. At each station, two replicate tows are taken at the surface and at mid-d ep th. Zooplankton samples at each station are taken during day and night on two consecutive days for a total of 16 samples at each station for each sampling period.

Environmental Parameters At each station, dissolved oxygen and water temperature are determined using a YSI 57 Do meter. Salinity is mea.1ured on a YSI 33 'SCT meter. Bo th m3ters are calibrated daily in the field. Percent cloud cover is estimated daring the collecting of zooplanktea samples.

I-13

s

_ Laboratory Operation Quality Control Review The processing of samples from the Crystal River Community Structure Study is assured of quality control by a quality control team organized specifically for this project. Members of this team are among the leading experts in their respective fields in the south Florida area. Geir names, af filiations and areas of participation are listed below.

Dr. Jeffray S. Prince Macroalgae University of Miami l

Mr. Mar k P. McMahon Aquatic Vascular Plants Connell Metcalf & Eddy Dr. Harding B. Michel Zooplanktois (as of December 1979)

University of Miami Mr. Lawrence W. Clow Annelids University of Miami Dr. Lowell P. Thomas Crustaceans, Mollusks and University of Miami other Phyla and Mr. Julio Garcia-Gomez Connell Metcalf & Eddy and University of Miami

! Mr. Ed Zillioux Zooplanicton (through June 1979)

Connell Metcalf & Eddy

(

Much time was expended during the initial phases of this wor k by the quality control team to organize the sorting and identification procedures and to l

I assure the accuracy of the initial identifications. Throughout the course of the study each member of the team confirmed both species identifications and I-14

numbers of individuals from representative samples, and checked the accuracy of all voucher collections within their specific areas of responsibility.

Bottom Core samples Each bottom oore sample is washed twice in freshwater through 2 mm and 0.5 mm sieves. This results in " coarse" and " fine" fractions. Each fractior. is sorted under the dissecting scope into four general categories of vermiforms,

~

crustaceans, mollusks, and others. These groups are transferred to a solution of 40% isopropyl alcohol. Polychaetes, mollusks, and crustaceans are identified to species or to family; all other groups are identified to phylum. For biomass determinations, the preserved wet weights for the groups are recorded. The grouped samples are then dried at 70 C for 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months and reweighed on a Mettler H10 balance to obtain dry weights. Each replicate sample is analyzed separately.

Venturi Samples Each venturi sample is washed in freshwater and sieved through a 2 mm mesh. The resulting sample is placed into a large glass sorting tray and sorted by hand into the four major groups described above. Any organism less than 0.3 cm in length is not counted to avoid bias due to differential clogging of the 0.3 cm mesh collecting bag. Identifications and biomass i

! determinations are identical to those described for the bottom core samples.

1-15

l I

l l

Benthic Plant Samples 'N 1

Benthic plant samples are sorted into seagrass and macroalgae fractions.

The seagrasses are identified to species. In each sample fifty leaves (if available) of each species are measured to the nearest millimeter. Mean leaf length and standard error are calculated for each species. Seagrass biomass determination is the same as for core and venturi samples, except that an Ohaus Harvard Trip Balance is used for wet weights of large samples. Biomass is determined by species.

Macroalgae are identified to genus. Biomass is determined by the method described above for seagrasses. Macroalgae biomasses are determined for divisions (Rhodophyta , Chlotophyta , Phaeophyta) .

Oyster Reefs Oyster reef samples are sorted in a large glass tray. Crustaceans and mollusks other than oysters (Crassostrea virginica) are placed into jars of 40% isopropyl alcohol and identified to species. Adult oysters and spat are separated (" adults" are distinguished from " spat" by having shell lengths greater than 2 cm), and the numbers of each are recorded. Each adult oyster is opened, the shell length measured to the nearest millimeter, and the meat placed into jars of 40% isopropyl alcohol. Mean oyster shell length and standard error are calculated for each sample. Biomass determinations for oyster meat are made on the triple beam balance, dried for 48 hours5.555556e-4 days 0.0133 hours 7.936508e-5 weeks 1.8264e-5 months at 90 C, and reweighed. The procedures used in biomass determinations for the crustaceans, spat and other mollusks are identical to those described for bottom cores.

I-16

I zooplankton Samples Aliquots of the zooplankton samples are prepared by using a modification of the Langford Plankton Sub-sampler as described by C. E. Cushing, Jr.

(1961). The aliquot size depends on the amount of phytoplankton and relative density of zooplankton organisms. Taxonomic identifications and counts are determined under the dissection scope with the use of a channelled slide of 6 ml capacity. All unususi sample characteristics are recorded. The , number of

~

organisms m are determined by the following formula:

YNC y

= number organisms m-3 where Y = the inverse of the aliquot size, N = the number of counts, C = the aliquot correction factor, and V = the volume passing through the net, determined by the flow meter readings. Biomass determinations are made by weighing aliquots of the samples, drying at 60 C for 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months , and reweighing . These weights are multiplied by the inverse of the aliquot fraction and the aliquot correction factor to determine the biomass of the entire sample, voucher Collection Voucher specimens of all benthic taxa are maintained whenever possible. A photographic voucher collection of zooplankton has been compiled. The quality control team has confirmed the identifications of all voucher taxa.

I-17 1

t

)

l l

RESULTS T

l l

General Comments The data collected during the quarterly sampling periods of 1979 are 1

summarized in Figs. 4 through 79 and Tables 1 through 13. For reference j purposes, all raw data and the basic statistical analyses of these data have l

been coded by taxon, station, basin and sampling period and stored in a computer-retrievable system. The results reported here are presented in sections which correspond to the type of sample collected. . Animals collected by the venturi suction sampler and the bottom core sampler, however, are reported together in the section on benthic animals as they reprecent a l

l planned sampling redundancy within the same habitats. Appropriate statistical l

analyses of these data are included in the tables presented in Appendix B.

i A complete list of all benthic and zooplankton taxa collected during 1979 is given in Tables 1, 2 and 3 collectively. The relative frequency of l

occurrence of each benthic or oyster reef taxon (Tables 1,and 2, respectively) ,

is indicated by the percentage of control or discharge stations where it was found. The relative freqpency of occurrence of each zooplankton taxon (Table

3) is indicated by the percentage of control or discharge samples in which it was found. Over the year, these percentages are based upon 48 benthic l

stations (20 control; 28 discharge), 36 oyster reef stations (12 control; 24 1

discharge) and 96 zooplankton samples (48 control; 48 discharge).

1-18

Table 1. Taxonomic list and relative occurrence of benthic organisms (excluding orginisms found only on oyster reefs), in the vicinity of Florida Power Corporation's Crystal River Plant. (Each relative occurrence datum is the percentage of 20 control stations or 28 discharge stations where occurrence was recorded. A relative occurrence of zero for both the control and discharge basins indicates species presence in 1977 or 1978, but not in 1979. Samples were collected during March, June, September and December 1979.)

Relative Occurrence Control Discharge Taxon Family S ta tions Stations PHYLUM ANNELIDA, CIASS POLYCHAETA Amphicteis gunneri Ampharetidae 0 0 Apoprionospio pygmaea Spionidae 0 0 Arabella iricolor Arabellidae 73 0 Arabella irudescens Arabellidae 0 0 Arenicola cristata Arenicolidae 5 0 Aricidea fragilis Paraonidae 0 4 Aricidea philbinae Paraonidae 85 100 Aricidea taylori Paraonidae 95 100 Aricidea sp. Paraonid a 45 89 Axiothella mucosa Maldanid2e 75 35 Branchicasychis americana Maldanidae 50 18 Brania clavata Syllidae 20 7 Capitella capitata Capitellidae 85 75 Ceratonereis irritabilis Nereidae 10 7 Ceratonereis sp. Nereidae 5 7

Chone duneri Sabellidae 70 46 Chone sp. Sabellidae 15 0 Clymenella torquata Maldanidae 15 21 Dr sybranchus lumbricoides Capitellidae 0 0 Diopatra cuprea Onuphidae 25 57 Enoplobranchus sanguineus Terebellidae 15 0 Eteone heteropoda P hyllodocidae 40 11 Eumida sanguinea Phyllodocidae 5 0 Eunice atennata Eunicidae 5 0 Eunice pinnata Eunicidae 0 0 Exogone dispar Syllidne 80 29 Exogone sp. Syllidae 0 0 Fabricia sabella Sabellidae 0 0 Fabricia sp. Sabellidae 95 54 Glycera americana Glyceridae 55 54 Glycinde solitaria Goniadidae 0 0 Glycinde sp. Goniadidae 75 14

Gy,ptis brevipalpa Hesionidae 75 57 Haplosooloplos foliosus Orbiniidae 0 4 t

! I-19 l -

l Table 1. (Con t. ) l 3

Relative Occurrence Control Discharge Taxon Family S ta tions S tations Haploseoloplos robustus Orbiniidae 85 39 Harmothoe aculeata Polynoidae 15 u Harmothoe sp. Polynoidae 0 0 Heteromastus filiformis Capitellidae 40 57 Hyboscolex longiseta Scalibregidae 15 0 Laeonereis culveri Nereidae 40 79 Lepidametria commensalis Polynoidae 30 ~4 Lepidonotus sp. Polynoidae 20 4 Loandalia fauveli Pilargidae 0 0 Loimia viridis Terebellidae 0 0 Lumbrineris sp. Lumbrinereidae 30 64 Lysidice ninetta Eunicidae 15 4 Lysilla alba Terebellidae 90 18 Magelona pettiboneae Magelonidae 70 79 Malacoceras vanderhorsti Spionidae 0 0 Malacoceras sp. Spionidae 0 4 Marphysa sanguinea Eunicidae 80 46 Mediomastus californiensis Capitellidae 90 75 Melinna maculata Ampharetidae 15 11 Minuspio cirrifera Spionidae 5 0 Minuspio cirrobranchiata Spionidae 0 0 Minuspio sp. Spionidae 0 4 Nainereis sp. Orbiniidae 70 7 Nematonereis unicornis Eunicidae 30 7 Nereis acuminata Nereidae 15 0 Nereis falsa Nereidae 30 ,

14 Nereis succinea Nereidae 55 50

~ Nereis sp. Nereidae 15 4 Notomastus latericeus Capitellidae O C Notomastus sp. Capitellidae 10 4 odontosyllis sp. Syllidae 30 4 Onuphis nebulosa Onuphidae 95 39 Owenia fusiformis Owen iidae 20 25 Parahesione luteola Hesionidae 0 0 Paramastis speciosa Capitellidae 0 0 Paranaitis speciosa Phyllodocidae 0 4 Paraon ides sp. Paraonidae 75 54 Paraon is sp. Paraonidae 0 0 Paraprionospio pinnata , Spionidae 60 86 Pectinaria gouldii Pectinariidae 5 4 Perinereis floridana Nereidae 0 0 Phyllodoce arenae Phyllodocidae 10 7 I-20 l

l Table 1. (Con t. )

Relative Occurrence Control Discharge

(

i Taxon Family Stations Stations Phy11odocidae 0 7

_P_hyllodoce sp.

Pilargis sp. Pilargidae 0 0 Flabelligeridae 30 0 l Piromis eruca Pista cristata Terebellidae 40 7 Pista palmata Terebellidae 30 0 Pista sp. Terebellidae 20 0 Platynereis dumerilii Fereidae 50 '4 Poecilochaetus johnsoni Poecilochaetidae 15 4 Polydora websteri Spionidae 75 71 Spionidae 0 4 Polydora sp.

Polyondentes lupina Polyondontidae 0 0 Prionospio heterobranchia Spionidae 75 64 Sabella micropthalma Sabellidae 15 4 Sabellaria vulgaris Sabellariidae 60 7 l

sabellaria sp. Sabellariidae 0 0 l

Schistomeringus rudolphi Dorvilleidae 40 11 Soolelepis squamata Spionidae 35 57 Sooloplos rubra Orbiniidae 95 50 Scyphoproctus platyproctus Capitellidae 40 4 Sigambra bassi Pilargidae 0 0 Sphaerosyllis sp. Syllidae 15 4 i Spio pettibonae Spionidae 0 0 Spiochaetopterus costarum Chaetopteridae 10 7 Spiophanes 42mbyx Spionidae 0 0 Streblosoma hartmanae Terebellidae 65 7 Streblospio benedicti Spionidae 10 . 61 Syllides sp. Syllidae ,0 0 Syllis sp. Syllidae 100 68 Terebellides stroemi Terebellidae 5 0 Tharyx sp. Cirratulidae 100 86 unio. sp. Ampharetidae 0 0 Arabe111dae 5 0 unid. sp.

un id. sp. Capitellidae 80 46 Chry sope talidae 5 0 unid sp.

unid. sp. Cir ra tulidae 5 11 Dorvilleidae 0 0 unid. sp.

Eunicidae 5 7 unid, sp.

unid. sp. Hesionidae 30 11 l 0 unid. sp. Lumbrinereidae 0 unid. sp. Maldanidae 25 14 unid sp. Nereidae 85 36 Opheliidae 0 0 unid. sp.

l I-21

Table 1. (Con t. )

Relative Occurrence Control Discharge Taxon Family S tations S ta tions mid. sp. Orbiniidae 10 4 unid. sp. Paraonidae 20 25 unid. sp. Phyllodocidae 35 21 triid, sp. Polynoidae 0 0 unid. sp. Sabellidae 50 18 mid. sp. Scalibregmidae 0 .0 unid, sp. Serpulidae 80 11 unid. sp. Spionidae 40 21 unid. sp. Syllidae 35 14 unid. sp. Terebellidae 35 7 PHYLtM ANNELIDA unid. sp. -

0 0 PHYLtM ANNELIDA, CLASS OLIGOCHAETA unid, sp. -

100 86 PHYLLN ANNELIDA, CLASS ARCHIANNELIDA unid. sp. -- 0 0 PHYLLM MOLLUSCA, CLASS GASTROPODA Acteocina canaliculata Acteocinidae 50 86 Ac teocina bullata Acteccinidae 0 0 Acteocina sp. Acteocinidae 0 -

0 Acteon punctostriatus Acteccinidae 0 0 Acteon sp. Acteocinidae 0 0 Anachis obesa Columbellidae 15 4 Anachis pulchella Columbellidae 0 0 Bittium varium Cerithiidae 25 61 Bulla striata Bullidae 40 11 Bulla sp. Bullidae 10 4 Caecum pulchellom Caecidae 15 14 Caecum sp. Caecidae 40 25 Calatrophon ostrearum Muricidae 25 0 Cancellaria reticulata Cancellaridae 20 11 Cerithiopsis emersoni Cerithiidae 10 0 Cet ithlum eburneum Cer ithiidae 5 4 Cetithlidae 75 14

_C_er ith lum muscarum Cer ithium sp. Cet ith ildae 0 0 Costoanachis semiplicata Columbellidae 45 0 i I-22

Table 1. (Con t. )

Re,lative Occurrence Control Discharge Taxon Family Stations Stations Crassispira tampaensis Turridae 10 0 Crepidula aculeata Calyptraeidae 20 0 Crepidula maculosa Calyptraeidae 85 7 Crepidula plana Calyptraeidae 60 11 Crepidula sp. Calyptraeidae 25 7 Cylindrobulla beavii Volvatellidae 30 0 Diadora _cayenensis Fissurellidae 0 0 Diadora jaumei Fissurellidae 3 0 Epitonium sp. Epitoniidae 0 0 Fascio1 aria lilium Fasciolariidae 20 0 Fasciolaria sp. Fasciolariidae 0 0 Granula ovuliformis Marginellidae 25 4 Haminoea sp. Haminoeidae 20 11 t Margine11a apicina Marginellidae 70 7 Margine11a aureocineta !!arginellidae 10 0

(

Margine11a lavaleeana Marginellidae 5 4

~

Marg inella sp. Marginellidae 10 0 Melanella sp. Melanellidae 0 0 Melongena corona Melongenidae 0 0 Microdochus sp. nis coidae 0 4 Mitrella dichroa Columbellidae 5 0 Mitre 11a lunata Columbellidae 70 46 Nassarius vibex Nassaridae 80 71 Odostomia laevigata Pyramidellidae 0 4 Odostomia sp. Pyramidellidae 50 36 Olive 11a mutica Olive 111dae 5 0 011 vella sp. Olivellidae 35 - O Polinices duplicatus Natacidae 10 0 Pyramidella sp. Pyramidellidae 0 0 Pyrgocythara glicosa Turridae 5 4 Pyrgospira ostrearum Turridae 0 0 l Rissoina sp. Rissoinidae 10 4 Seila adamsi Cerithidae 10 4 Strombiformis sp. Strombidae 0 0 Teinostoma sp. Vitrine 111dae 35 7 Terebra protexta Terebridae 5 0 1

Turbonilla interrupta Pyramidellidae 0 4 Turbonilla sp. Pyramidellidae 45 7 Urosalpinx tampaensis Muricidae 20 0 4

vitrine 11a floridana vitrinellidae 0 unid. Gastropod ----- 0 7 unid. sp. Columbellidae 0 0 I-23

l \

l l

Table 1. (Con t.)

Relative Occurrence '

f Control Discharge Taxon Family S ta tions S ta tions tstid. sp. Marginellidae 0 0 tmid. sp. Melanellidae 0 0 unid. sp. Nudibranchia 0 4 taid, sp. Turridae 0 0 unid sp. Vitrinellidae 0 0 PHYLLtM MOLLUSCA, CLASS BIVALVIA Abra aequalis Semelidae 5 0 Aequipectin sp. Pectinidae 5 0 Allgena texasiana Leptonidae 5. .

O Amygdalum papyrium Mytilidae 5 7 Arcopsis adamsi Arcidae 0 0 Argopecten irradians Pectinidae 0 0 Brachidontes domingensis My ti) ' dae 10 0 Brachidontes exustus Mytiiidae 15 0 Brechidentes sp. Mytilidae 20 11 Carditamera floridana Carditidae 55 11 Chione cancellata Veneridae 20 4 Chione sp. Veneridae 5 0 Coda kia sp. Lucinidae 5 0 Corbula contracta Corbulidae 5 0 Corbula dietziana Corbulidae 5 0 Corbula swif tiana Corbulidae 0 0 Corbula sp. Corbulidae 15 7 Crassostrea virginica Ostreidae 30 7 Cumingia coaretata semelidae 5 . 7 l

Cumingia tellinoides semelidae 5 0 Cumingia sp. Semelidae 10 4 Cyclinella tenuis veneridae 5 0 Ensis minor Solen id.e 0 4 Gemma sp. Veneridae 0 0 Ischadium recurvum Mytilidae 15 0 Laevicardium laevicatum Ca rdiidae 20 0 Laevicard f um mor toni Cardiidae 65 14 Lima pellucida Limidae 5 0 Lieberus castaneus Mytilidae 0 0 Lucina nassula Lucinidae 5 0 Lyonsia _hyalina Lyonsiidae 35 39 Macoma constricta Tellinidae 5 0 Mactra fragilis Mactridae 20 0 Mercenaria campechiensis Venecidae 5 0 I-24

Table 1. (Con t. )

Relative Occurrence l

I control Discharge Family Stations Stations Taxon 25 0 Musculus lateralis Mytilidae Mysella planulata Leptonidae 5 7 Leptonidae 0 0 Mysella sp. 0 Nucula proxima Nuculidae 35 Nuculidae 5 7 Nuculana sp.

Ostrea equestris Ostreidae 45 4 Parastarte triquetra Veneridae 0 ,0 Periploma sp. Periplomatidae 75 36 Carditidae 0 0 Pleuromeris tridentata 7 Semele porficua semelidae 35 Semele purpurescens semelidae 5 0 Semele sp. Semelidae 0 11 Solemyacidae 0 0 Solemya sp.

Tagelus divisus solecurtidae 0 0 Tellinidae 0 0 Tellina lineata Tellinidae 5 0 Tellina nitens Tellinidae 5 11 Tellina texana Tellina sp. Tellinidae 55 43 Trachycardium muricatum Cardiidae 5 0 Trachycardium sp. Cardiidae 5 0 Veneridae 30 0 Transennella contadina Transennella sp. Veneridae 5 0 Arcidae 0 0 unid. sp.

unid. sp. Carditidae 0 0 Leptonidae 0 0 unid. sp.

Ostreidae 0 0 unid. sp.

unid. sp. Semelidae 0 . O Tellinidae 0 0 unid. sp.

0 0 unid. Bivalvia -

PHYLUM HOLLUSCA, CLASS AMPHINEURA l

Ishnochiton papillosus Ischnochitonidae 50 4 Acanthoch itonidae 35 4 Acanthochitona pygmaea unid. sp.

PHYL1H ARTHPOPODA, CIASS CRUSTACEA Subclass Ostracoda I-25

Table 1. (Con t. )

Relative Occurrence )

Control Discharge Taxon Family Stations S ta tions inid. sp. -

90 89 Subclass Copepoda imid. sp. - 0 0 Order Calanoida Acartia tonsa Acartiidae 20 4 Pseudo 3iaptomus coronatus Diaptomidae 0 4 Te:nora turbinata Temoridae 0 4 25' 21 unid, sp.

Order Cyclopoida unid, sp. -- 15 7 Order Harpacticoida unid. sp. -- 5 14 Subclass Malacostraca Order Cumacea unid. sp. Diastylidae 20 25 unid. sp. non-Diastylidae 5 18 unid. Cumacea - 10 18 Order Tanaidacea Kalliapseudes sp. Kalliapseudidae 15 11 unid sp. Kalliapseudidae 5 0 unid sp. Mono konophora 65 32 mid. sp. Dikonophora 35 11 Order Isopoda unid. sp. Aegidae 10 0 unid. sp. Anthuridae 45 36 unid. sp. Cirolanidae 0 0 mid sp. Excorallinidae 20 4 unid. sp. Idote idae 60 54 I-26 l

[

Table 1. (Con t. )

Relative Occurrence Control Discharge Taxon Family Stations S tations unid, sp. Sphaeromatidae 70 25 mid. Isopoda - 5 4 Order Amphipoda unid. sp. Ampeliscidae 65 50 unid. sp. Amphilochidae 50 4 unid. sp. Ampithoidae 70 43 unid, sp. Aoridae 100 61 unid. sp. Bateidae 55 11 unid. sp. Caprellidae 75 21 unid. sp. Colomastigidae 5 0 unid. sp. Corophiidae 75 43 unid. sp. Hyalidae 0 0 unid. sp. Leucothoidae 25 7 unid. sp. Liljeborgiidae 60 7 unid. sp. Lysianassidae 15 0 unid. sp. Melitidae 80 21 unid. sp. Oedicerotidae 10 0 unid. sp. Phliantidae 20 0 unid. sp. Phoxocephalidae 65 4 unid. sp. Podoceridae 0 4 unid. sp. Pontogeneidae 20 0 unid. sp. Stenothoidae 5 0 unid sp. -- 10 0 l

Order Mysidacea

unid. sp. -- 25 O Order Decapoda f Alpheus armiliatus Alpheidae 20 4 A1pheus heterochaelis Alpheidae 55 46 Alpheidae 40 11 Alpheus normannii Alpheus sp. Alpheidae 45 21 Ambidexter symmetricus Hippolytidae 45 43 Automate sp. Alpheidae 5 0 Callinectes sapidus Por tunidae 0 4 Callinectes sp. Por tunidae 5 7 l

Eurypanopeus abbreviatus Xan thidae 0 0 Xan thidae 70 18 Eurypanopeus depressus Xan thidae 5 0 Eurypanopeus sp.

hexapanopeus augustifrons Xan thidae 0 0 l

1-27

Table 1. (Con t. ) 3 Relative Occurrence Control Discharge Taxon Family Stations S ta tions Hexat _nopeus sp. Xanthidae 5 0 Hippolyte pleuracantha Hippolytidae 70 46 Hippolyte sp. Hippolytidae 10 0 Latreutes fucorum Hippolytidae 10 0 Libinia dubia Majidae 35 0 Libinia sp. Majidae 5 0 Metophorhaphis sp. Majidae 10 ,0 Neopanope packardi Xanthidae 25 4 Neopanope texana Xanthidae 50 18 Neopanope sp. Xan thidae 65 36

_ogyrides limicola Ogyridae 5 4 Ogyrides yaquiensis Ogyridae 10 0 ogyrides sp. Ogyridiae 5 7 Palaemon floridanus Palaemonidae 5 0 Palaemon sp. Palaemonidae 0 0 Palaemonetes inte'rmedius Palaemonidae 30 29 Palaemonetes pugio Palaemonidae 20 7 Palaemonetes vulgaris Palaemonidae 0 0 Palaemonetes sp. Palaemonidae 10 21 Pagurus annulipes Paguridae 0 0 Paguru s spp. Paguridae 90 43 Panopeus herbstii Xanthidae 10 0 Panopeus occiden talis Xanthidae 25 11 Panopeus sp. Xan thidae 10 7 Pelia mutica Majidae 10 0 Penaeopsis sp. Penacidae 0 0 Penaeus duorarum Penacidae 5 . O Penaeus sp. Penaeidae 30 25 Periclimenes americanus Palaemonidae 40 14 Periclimenes longicaudatus Palaemonidae 50 14 Periclimenes sp. Palaemonidae 10 7 Petrolisthes armatus Porcellanidae 20 0 Petrolisthes sp. Porcellanidae 20 7 i Pinnirl sp. Pinnotheridae 60 39 i Pitho anisodon Majidae 0 0 Rithropanopeus harrisii Xan thidae 20 4 Thor dobkini Hippolytidae 5 0 Thor floridanus Hippolytidae 20 4 Thor sp. Hippoly tidae 5 0 Tozeuma carolinense Hippolytidae 10 11 Trachypenaeus sp. Penaeidae 10 0 Ugogebia a f fin is Callianassidae 25 14 1 unid. sp. Alpheidae 5 0 )

r 1-28

i l

i l l

[ Table 1. (Cont. ) i l

Relative Occurrence Control Discharge l Taxon Family Stations S tations i

un id. sp. Callianassidae 5 7 unid, sp. Grapsidae 0 0 unid. sp. Hippolytidae 25 7 l 0 l

unid. sp. Majidae 5

! unid. sp. Paguridae 5 4 I Palaemonidae 25 7 unid. sp.

unid. sp. Penaeidae 10 0 unid. sp. Pinnotheridae 5 4 unid. sp. Porcellanidae 0 '4 unid, sp. Por tunidae 0 4 unid. sp. Processidae 0 7 unid. sp. Xanthidae 85. .

43 unid. sp. Caridean 10 0 unid. sp. Brachyuran zoea 0 4 unid. sp. Caridean zoea 10 7 unid. Natantia -- 0 11 unid. sp. post larvae 10 0 unid, sp. megalopa 15 4 unid. Reptantia -- O 11 Subclass Cirripedia Balanus sp. Balanidae 25 14 Subclass Cephalocaridia unid. sp. -- 0 0 80 64 PHYLUM ECHINCDERMATA 80 43 PHYLUM ASCHELMENTHES 65 18 PHYLUM SIPUNCULA 100 64 PHYLUM NEMERTINEA l

40 18 l ,

PHYLUM PLATYHELMINTHES PHiLQ4 CHORDATA 85 0 CLASS ASCIDIACEA l

I-29

l l

Table 1. (Con t. )

Relative Occurrence )

Control Discharge

, Taxon Family Stations Stations CIASS OSTEICHulYES 95 61 PHYLtM PORIFERA 75 21 PHYLtM CHAETOGNAMIA 5 7 PHYLIM ODELENTERATA 10 11

~

PHYLIN EC'10PBOCTA 0 0 MACBOALGAE DIVISION RHODOPHYTA Centroceras sp. Ceramiaceae 10 0 Ceramium sp. Ceramiaceae 5 0 Champia sp. Champiaceae 10 0 Chrysymenia sp. Rhodoymeniaceae 0 0 Chondrla sp. Rhodomelacese 35 0 Dasya sp. Dasyaceae 15 0 Digenla sp. Rhodomelaceae 10 4 Gracilaria sp. Gracilariaceae 60 0 Hypnea sp. Hypneaceae 0 0 Laurencia sp. Rhodomelaceae 10 0 Polysiphonla sp. Rhodomelacese 0 0 Spyridia sp. Ceramiaceae 45 . O DIVISION PHAEOPHYTA Dictyota sp. Dictyotaceae 0 0 Rosenvingea sp. Punc tariaceae 10 0 Sargassum sp. Sargassaceae 55 0 Sjictyosiphon sp. Striatiaceae 10 0 Stilophora sp. Stilophoraceae 5 0 DIVISION CHLOBOPHYTA Acetabularia sp. Dascyladaceae 0 0 Caulerpa sp. Caulerpaceae 70 0 I

l I-30

Table 1. (Con t. )

Relative Occurrence Control Discharge Taxon Family Stations Stations cladophora sp. Cladophoraceae 0 0 Halimeda sp. Codiaceae 5 0 Penicillus sp. Codiaceae 0 0 Udotea sp. Codiaceae 10 0 SEAGRASSES _

Halodule beaudettei Cymodoceaceae 20 64 Halophila engelmannii Hydrocharitaceae 5 0 Ruppia maritima Ruppiaceae 20 0 Syringodium filiforme Cymodoceaceae 25 0 Thalassia testuo tnum Hydrocharitaceae 0 0

{

Note: The following taxonomic revisions to this list have been made:

Anachis semiplicata is now Costoanachis semiplicata; Nucula crenulata has been correctly identified as Nucula proxima; Eurypanopeus dissimilis has been merged with Eurypanopeus depressus Hippolyte zostericola has been merged with Hippolyte pleuracantha.

l I-31

Table 2. Taxonomic list and relative occurrence of benthic organisms on oyster reefs in the vicinity of Florida Power Corporation's Crystal River Plant. (Each relative occurrence datum is the percentage of 12 control or ]

24 discharge stations where occurrence was recorded. Samples were oollected during March, June, September and December 1979.)

l l

Relative Occurrence l

Control Discharge Taxon Family S tations Stations PHYLtM MOLLUSCA, CIASS GASTROPODA Cerithiopsis emersoni Cerithiidae 8 0 Cerithiidae 17 0 Cerithium muscarum Crepidula maculosa Calyptraeidae 25 _0 Calyptracidae 8 0 Crepidula aculeata Crepidula plana Calyptraeidae 100 14 Fasciolariidae 8 0 Fascio1 aria lilium 0 Melongena corona Melongenidae 17 Nassaridae 8 0 Nassarius vibex Odostomia impressa ?yramidellidae 8 0 Pyramidellidae 8 9 Odostomia sp.

33 0 Seila adamsi Cerithiidae PHYLtM MOLLUSCA, CLASS BIVALVIA

Brachidentes spp. Mytilidae 100 75 Ca rditidae 67 0 Carditamera floridana 0 Chione sp. Veneridae 8 Corbulidae 8 0 Corbula swif tiana Corbulidae 17 0 Corbula sp.

Crassostrea virginica Ostreidae 100 100 Ostrea equestris Ostreidae 67 0 Semele porficua Semelidae 50 5 PHYLUM MOLLUSCA, CIASS AMPHINEURA Acanthochitona pygmaea Acanthochitonidae 17 0 Ischnochiton papillosus Ischnochitonidae 17 0 l

PHYLUM ARDIROPODA, CIASS CRUSTACEA Subclass Malacostraca Order Tanaidacea Dikonophora 0 0 unid. sp.

l I

1-32

. 1

Table 2. (Continued)

Relative Occurrence i

~

Control Discharge Taxon Family Stations Stations Order Amphipoda umid. sp. Hyalidae 83 68 umid. sp. Melitiele 17 0 l unid. Amphipoda - 0 0 l

Order Decapoda Eurypanopeus depressus Xanthidae 100 86 Eurypanopeus sp. Xanthidae 0 0 Neopanope packardi Xan thidae 0 0 Pagurus sp. Paguridae 8 0 Panopeus herbstii Xan thidae 100 82 Panopeus occidentalis Xanthidae 33 5

( Panopeus sp. Kanthidae 17 0 I Petrolisthes armatus Porcellanidae 75 18 Petrolisthes sp. Porcellanidae 58 41 Rithropanopeus harrisii Xan thidae 8 0 Uca pugilator Ocypodidae 0 0 Uca sp. Ocypodidae 0 18 l

l unid. sp. Grapsidae 0 0 unid sp. Xan thidae 100 86 Subclass Cirripedia Balanus sp. Balanidae 100 82 Phylum Insecta ,

Anurida maritima Poduridae 33 23 l tmid, arachnid -

0 0 l

Brachidontes spp. is a combination of Brachidontes domingensis, Brachidontes exustus and Ischadium recurvum.

I-33

l l

l Table 3. Taxcriomic list and relative occurrence of zooplankton in the vicinity of Florida Power Corporation's Crystal River Plant. (Each 3' ,

relative occurrence datum is the percentage of 48 discharge or 48 centrol samples where occurrence was recorded. Samples were collected during

June and December 1979.)

Relative Occurrence Control Discharge Taxon Samples Samples PHYLIM COELENTERATA CLASS HYDROZOA unid. Anthomedusae 10 8 triid. Leptomedusae 10 -

12 unid. Siphonophora 4 O mid. sp. 2 0 CIASS SC7PIOZOA Scyphozoan medusae 6 0 PHYLIE PLATYHELMINTHES mid. spp . 0 0 PHYLtM ANNELIDA CIASS POLYCHAETA unid. sp. 4 6 tmid. larvae 81 39 PHYLLM EC'IOPROCTA unid, cyphonautes larvae 17 17 PHYLtM CHArrOGNATHA Sagitta sp. 81 62 unid. sp.

I-34

Table 3. (Con t. )

p lative occurrence control Discharge Taxon Samples Samples PHYLIM MOLLUSCA CLASS GASTROPCDA unid. veligers 92 83 unid. Pteropoda 0 0 CIASS BIVALVIA .

unid. veligers 100 79 tmid. species, juvenile 0 0 PHYLtM ECHINODERMATA 2

unid. Brachiolarian larva 0 CLASS OPHIUROIDEA unid. ophiopluteus 4 2 unid. echinopluteus 0 0 PHYLIM ASCHELMINTHES CLASS NEMATCDA 2 0 unid. spp.

PHYLlM CHORDATA l

CIASS OSIEICHTHYES I

unid, eggs 15 17 15 6 unid. larvae 0 0 unid. juveniles l

I-35

Table 3. (Con t. )

N Relative Occurrence Control Discharge l Samples Samples Taxon SUBPHYLLM TUNICATA CLASS ASCIDIACEA unid. larvae 17 2 mid. sp. 2 0 CIASS LARVACEA unid. sp. 50 69 PHYLtM ARTHROPODA, CLASS CRUSTACEA mid. sp. 2 0 unid. larvae 10 2 Subclass Copepoda unid. sp. 17 6 mid nauplii 83 69 Order Calanoida unid. nauplii 0 0 mid. sp. 0 2 Acartia tonsa 100

100 Centropages ef. hamatus 52 21 Labidocera mirabilis 29 12 l

Labidocera scotti 27 15 i Labidocera sp. 0 0 1 Paracalanus crassirostris 100 98 Paracalanus parvus 38 46 Pseudor!iaptomus coronatus 98 96 Tenora turbinata 69 52 Tor tanus setacaudatus 8 8 Order Cyclopoida Corycaeus spp. 4 0 Oithona spp. 96 88 unid spp. 6 10 i

I-36

Table 3. (Con t. )

Relative Occurrence Control Discharge Taxon Samples Samples Order Caligoida Caligidae 6 12 Order Narpacticoida Alteutha sp. 4 2 Euterpina acutif rons 90 81 Long iped is sp. 67 54 Metis sp. 0 2 Microsetella sp. 0 ,

0 Porcellidium sp. 0 0 tmid, spp. 73 75

(

Tegastidae 12 19 l

l l

Order Monstrilloida unid, sp. 2 0 Subclass Cirripedia taid. nauplii 96 98 tmid, cyptis 65 60 Subclass dstracoda unid. spp 2 4 Subclass Branchiopoda Order Cladocera unid. sp. 6 4 Subclass Malacostraca Order Amphipoda unid, spp. 10 10 I-37

Table 3. (Con t. ) 3 Relative Cerurrence i Control Discharge Taxon Samples Samples Order Mysidacea unid. spp. 12 10 Order Cumacea unid. spp. 8 25 Order Isopoda unid. spp. 73 42

Order Tanaidacea unid. sp. 0 0 Order Decapoda unid. larvae 0 0 Suborder Natantia caridean zoea 81 52 Crangonid larvae 2 0 Crangonid zoea 4 0 mysis larvae 2 2 post larvae 0 . 0

Hippolyte pleuracantha 2 0

Hippolyte sp. 2 0 Lucifer sp. 23 4 Periclimenes sp. 0 0 Suborder Reptantia

! porcellanid zoea 15 15 brachyuran zoea 44 38 megalopa 0 4 Paguridae (Anomura) 0 0

Note: Net dragged bottom I-38

Table 3. (Cont.)

Relative Occurrence Control Discharge Samples Samples Taxon PBYLIM AR'DIROPODA, CIASS ARACHNIDA Order Acarfm 2 0 unid, sp.

PHYLIM ARTHROPODA, CLASS PYCNOGONIDA 0 0 unid. sp.

Note: Harpacticoid sp. A reported in 1977 and 1978 has been identified as Longipedia sp.

i 1

l l

I-39

Statistical Treatment

]

Basic statistical data (means, standard deviations and ranges) are presented in tables found in Appendix B for the bottom core, venturi and sooplankton samples. T-tests and related descriptive statistics are presented in Table B-7 of Appendix B. Significant control / discharge comparisons are discussed in the following sections. Homogeneity of variances was tested prior to comparing the basin teruits by t-tests. Log (x + 1) transformation of the data was utilized in cases where variances were shown to be significantly differents no t-tests were run for data sets showing non-homogeneous variance.

Throughout this report, statistical comparisons are made between overall control and overall discharge data. These are done for several reasons, the most important of which is that the effects of interest in statistical testing for this study are overall basin effects, not individual station effects.

Further, and more specific, testing is anticipated at the conclusion of the fourth year of the study.

o Comparisons with Pre-Operational Data In an effort to determine if changes have occurred in community structure since the ccamencement of Unit 3 operation, field and laboratory observations have been compiled to form a data base for comparisons with pre-operational t

l studies. The pre-operational studies were undertaken in 1973 and 1974 by l

investigators at the University of Florida and the University of South i

I-40

Florida. These studies were compiled into a final report submitted to Florida Power Corporatica in 1974.

Due to dif ferences in field collection times, locations, techniques and data analysis, only a f ew groups of data within the 1977-1978-1979 sampling periods are sufficiently similar for direct comparison with the pre-operational study. These groups include mean macrophyte biomass and diversity by taxon (discussed in the section on Seagrass and Macroalgae);

oyster and spat abondance and biomass on reefs (discussed in the section on Oyster Reefs); venturi abundance and biomass; and salinity and temperature (discussed in the section on Benthic Animals) .

I There is little adequate comparative data available for the study area prior to the initial start-up of the two coal-burning plants in 1967. By the time of the pre-operational study, the discharge and control basins apparently had evolved into quite different physical and biological systems, probably in response to man-made changes. These include a long history of physical separation of the two basins by the present jetty system, catting and redirecting of tidal creeks, and thermal effluents from two fossil fuel plants which had been entering the discharge basin for several years. Direct comparisons between the two basins, therefore, are complicated by many other ,

factors besides the operation of Unit 3. To further complicate comparative analysis of pre-operational, 1977,1978 and 1979 data, Unit 3 was inoperative for nearly seven months in 1978, from 3 March to 29 September, and for over three months in 1979, from 23 April to 1 August. Therefore, in comparing pre-operational data with the 1977,1978 and 1979 data on the separate basins I-41

i l

I many factors sust be taken into consideration.

S l

Temperature and Salinity The mean temperature and salinity values for control and discharge inner basins during each sampling period are presented in Figs. 4 and 5, respectively. Mean temperature was significantly higher in the discharge basin than in the control basin for the March (r << 0.001), June (P << 0.001) and December (P << 0.001) sampling periods, but not for the September sampling per iod (0.05 < P < 0.1) . Mean salinity was significantly different (P < 0.005) between the basins for all 1979 sampling periods.

l l

I-42

TEMPERATURE 35- O- - - -O CONTROL

O DISCHARGE bN O

30- [_

1 ~

v

, Q --

g ,

- T--

Z p~ \

S r s

< 25- / s e / s __

U l s bi o_ ,

s E / g W / g H -

/ g z 20- j_ ' \

< -/ \

W /

Y E / .

X

/

d 15- ::

10 i i 1 i i . i l MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD F:g. 4 T.mp.e.tur. .t insid. st.tions of control .nd disch.co.

6..ios. ci... .c. ..... (e.na.et.. e r e i . .) . ,t.na.re d.,4. tion.

(r.ctangl.s) and ranges (h o r i z o n t a l bars).

I-43

s SALINITY 35- o- - - -O CONTROL 0 0 DISCHARGE

+ p Q- 3 0 -

o_

F- O Z --

~ A{

_a --

< 25- -

cn =_ Sk s

z ,'__ N s

\

L1J /

r __

--/

/

\

- a -

20-

__ l 1

15 ;

MkR f9 JUN f9 SEP f9 DEC f9 SAMPLING PERIOD F:g. 5. Salinity at inside stations or eontros and d;senerge besins. Given see means (c o nn e c t s o e l e c l e s) . stenoseo devietions (eectangles) anc ranges (ho r i z o n t a l Dars). l I-44

l l

L l Benthic Animals General Treatment Data on overall mean number of individuals, biomass, species diversity and evenness are given below under the separate subsection headings of Venturi Suction Samples, Bottom Core Samples and Total Animal Benthos. Where appropriate, comparable data on major taxonomic divisions (annelids, mollusks, crustaceans and other groups) also are presented, causing these subs ~ections to overlap with the following subsections on Annelids, Mollusks, Crustaceans, and Other Groups.

Additional treatment of benthic animals including comparisons with pre-operational data and discussions of post-operational trends is given in the various subsections entitled Post-operational Trends and Comparisons With Pre-operational Data.

Based upon the analyses of sample data on the separate taxonomic groups during both 1977 and 1978 post-operational studies, two assumptions are made which contribute to the general treatment of the overall year's data. These assumptions are that the venturi suction method and bottom core method sample partially difft. rent components of the benthic community, and that, combined, they effectively sample the benthic inf auna and epif auna.

The two methods of sampling benthic animals showed large differences in calculated mean numbers m-2 , the bottom core sampler generally I-45

sampled the smaller animals more effectively while the venturi suction sampler captured the larger animals more effectivoly. The major advantages of the

')

venturi suction sampler are its ability to sample an entire square meter rapidly with reasonable thoroughness, and its effectiveness at sampling hard and rocky bottom stations. Smaller sof t-bodied animals are easily damaged, however, and many whole animals, as well as fragments, are lost through the l

relatively large (0.3 cm) mesh of the collecting bag. The five replicates taken at each station with the bottom core sampler encompass a total sampling area of only 0.04 m . This appears adequate for sampling populations of small animals having a high frequency of occurrence but is ineffective for larger, less abundant animals. Generally, therefore, core analyses result in l

l the calculation of artificially low numbers of large animals per square meter. Occasionally, however, a chance capture of a large animal such as a starfish can produce artifically elevated numbers, thus resulting in highly erratic data. In the following subsections, therefore, dif ferences between techniques are taken into consideration in data analysis and data from core and venturi samples are always identified and listed separately, with the exception of the treatment of total number of taxa given in Fig. 7.

Venturi suction Samples The percent contribution of annelids, mollusks and crustaceans to total abundance in venturi samples is presented in Fig. 6A. The total number of i

! taxa of major groups at control and discharge stations from venturi and bottom core samples is presented in Fig. 7.

1-46

t I

rz . . ri ANNELIDS i i REMAINDER COR S CON 015 CON 015 CDs DIS CON DtS 100,, i LL.l -

O > :::

Z 5 ...

Q ...

z ...

50_ .. .. . .

m ...

O 25_ ..

i_._ .. . .....

z 0 .

O rr ci ANNELIDS in u m ni MD' LUSKS VENTURI g u t ili t ii r ii CRUSTACEA m i .

9EMAINDER com ois com ots com ois cow ots

% 100-- -___

i- ___

Z ~~~~

__ 1 O 75- :

O __

,__ l N _\' .,-- .,__

\' !

50- - ,

s- h....

\s T .,__ \

l i

. \ ....

2 5._ ,... . ,

0 .

MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig. 6. Percent contribution or ennelade. mollueke end crusteceone to total animal abundance In ventuel samples (A) and annelids to total enamel abundance in core semples (8). CON = control beein DIS = discharge beein.

1-47 1

i

~

\

l CORE & VENTURI

r. ..... ., egg 7agt MOLLUSKS

' " " 'i DISCHARGE 80-t l 60- _

40- ...

. ::. v ::. ::. C

< 20- N ...

3 g

k x ::.

. ::. N ::.

x 0 .

' W CRUSTACEANS u_

o x 80-uJ 5 CD 60- ::. =.

r -:,

=..

-z> 4 0- ::.

J20- ::. B n 0

h ...

- N -

O

! H ANNELIDS -

i 80- ...

= __

60- :: . ::. ::

1 l 40 -

20 -

. . .:.: A 0 u .::. ... .

MAR 79 JUN 79 SEP 79 DEC 79 l

SAMPLING PERIOD Fig. 7. Total number of toas of annelids (A). cruefeceens (8) and mollusks (C) et control and discharge stations.

I-48

l I

l The means, standard deviations and ranges of animal abundance sampled by the venturi suction method are shown in Fig. 8 for the control and discharge basins for the four sampling periods in 1979. *he means of the control samples were significantly higher than the means of the discharge samples in March (0.002 < P < 0.005), June (P < 0.001) and September (C.005 < P < 0.01), but not in December (0.20 < P < 0.50).

Abundance data for annelids, mollusks and crustaceans are presented in _

Figs. 9, 10 and 11. Biomass data for the annelids and crustaceans and mollusks are given for control and discharge basins in Figs.12 and 13, respec tively.

Bottom Core Samples The percent contribution of annelids to total abundance in bottom core samples is presented in Fig. 6B. Other data comparable to those presented for venturi samples for the bottom core samples are presented in Figs.14 through

16. The means, standard deviations and ranges of total animal abundance for control and discharge basins are given in Fig.14. As expected, the same data for annelids, given in Fig.15, are very similar. The degree of similarity between total animal and annelid abundance is a reflection of the conclusion arrived at during the 1977 study, that the annelids closely reflect overall benthic community fluctuations in abundance. Annelid biomass patterns (Fig.

16), however, bear little resemblance to community biomass patterns (Fig.

14-1), probably because the community biomass data is primarily composed of I I

mollusk biomass. Commun ity biomass is also considerably affected by the chance capture of large animals.

I-49 !

l l

l

m VENTURI CONTROL 1000- O- - - -O 0 DISCHARCE 7-r o

en .

x '-

800-en __

D a

3 600- --

a z

cr __

.g O r 400-CD -

Ar D -

z -

z 3 w ?

r 200- -

= :::. __

t

__w /

[ d g

MkR N9 JbN f9 SEP f9 DkC79 SAMPLING PER100 rio. 8. ns.n . bond.n.e ,or .eter soo. red or .ne..is ..iiecied in ventuel samplee in the control and discharge basins. GIwon are means (c o nn e c t e d e l e c l e s) , standsed devistions (r e c t a n c i e s) and ranges (h o r i z o n t a l b ar s) .

1-50

VENTUP,I 300- &---o 0

CONTROL 0 DISCHARGE ANNELIDS E

o m __

s 250-M

_J D

o 200- __ __

~

o __

Z

~ 150- --

o- __

L1J __

CD i E Z 100- o 1

> p l Z s' *

! < ,' /

LAJ #

- a /

E ,

g. __

50-

~

n --

w ~~

N

_ y __

0 -- == , ,

MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fis. 9. Mean abundance pec meter squared of annelids collected in ventuel samples in the control and diecharge bastne. Given are means (c o n n e c t e d e s ce l e s) . standsed devist!ons (r e c t an g l e s) and ranges (h o r i z o n t a l b ar s) .

1-51

l s

VENTURI 500- o- - - -O

=

CONTROL 0 DISCHARGE MOLLUSKS r __

o in N

400-en

_J D

Q __

~ --

3 300-o __

Z __

cr w

cn E 200-D --

z z a

< ==

w -

' s s

E 100- 3 -

e

's o JP

-- ,/

dl~~

==

l 0

~~

3 I MAR 79 JbN 79 SEP 79 DEC 79 SAMPLING PERIOD l Fig.10. Mean abundance per meter squared of mollusks collected l

in ventuel semples in the control and discharge basins. Given ere seens (c onne c t e d c i r c l e s) . stenderd devletions (rectangles) and ranges (hor i z on t a l b ar s) .

l I-52 l

VENTURI 700- >---o control CRUSTACEANS O O DISCHARGE r __

O M 600-N Ch

__J

< 500-D __

g

~

l

~

o 400-z

~

CC W

co 300-E z -

D z 200- / .-- -

4 -

g _ . _

g __

,- ~'

~'

, a 100- ,,,_ a __

& ~~

, ---O y

01 ==7

= _ _

MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig.11. Mean abundance per meter squared or crustaceans collected in ventuct semples in the control and discharge basins. Given are me.ns (c o n n e c t e d e le c l e s) . standard devistions (r e c t a n g l e s) and conges (h o r i z o n t a l b ac e) .

I-53

s VENTURI

&---O CONTROL ANNELIDS 1.00- 0 0 DISCHARGE l 0.80-1 --

^

E 0.60- --

@0.40- - -

s _' "__ ,,

=

0 & --

v 0.20-Y ~~

B U) g) 0.00

--g -

iN_

l E

O 0- - - -O CONTROL

~ CRUSTACEANS g O C DISCHARGE 30-z E

25-20-15- --

10- __

l o

5- & -

a

- o A 0- Eq mGEM J1 __

MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fis.12. Mesa bionese per meter equered or crustaceene (A) and annelide (8) collected in venturn semplee in the control and discharge bseine. G i v e r, ere meone (c onn e e t e d c i r c l e s) . etenderd devistions (r e c t a n g l e s) and rangee (hor t ion t a l b er e) .

I-54

l 1

VENTUR1

& - - --o coNTRot _ . _ nottusxs 5 :10 ' . e c OlsCHARGE 10" '

q -- __

- : s E '

'~ ~

/ "-

. / s O . / s A w ,

\ '

q / / \ --

O N / ' \

v s /

10' s C/ '

o

. s s

e /

cn :

d g .

/

E -

O .

a -- _

10o , l --

z : --

LLI -

E .

10 j -- --

, e

'. 1

~

1 10 *" --

MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fss.13. Mean biomees per meter enveced of motiveks colleetod in ventura semples in the control and discharge beelne. Civon are means (c o nne c t e d c ir c l e s) . siendeed devietione (rectangles) and ranges (horizontal bec e) .

I-55 i

l t

/ _

QDRn

' (

9 {u h,. zuQ> yow I

Q m O s$ n 0 O M a _

0 S a

/ i8 i1 c iI Il S a lI i'

L iI w"

A s ,11 s ,i U iI \

il , '

D g e w" I s , \

M w# ii N

V ,

I O s$

ia

, ii g N

D N

a a

iI gI ', N r h I

a

.w -w 1I I

lI R a iI E iI B a e ii M

U a s N ii

,i ia N a _

A

. E M rI a

1l m Ou - _ - - - - - -

I>W yW ecZ q@ no cm N@ OmO N@ _

A

( y2-y M2a y R2 OO _

T.*~b' x

- eE3 **C>" sa " , . e 7, ,j a e;; . ' .3.8*.

e , a ~ _ e h *e e G

9o** s 4o7o e.""_.e = r a ear %- * ( oo*;o- w "

_3e, "a=." ,*esae'* a

e "ose 9 es * '

B*e3e " ,3*, - o D ' _

7en O$ gee 2m 1.'".e 9 ; ;3.e- . vI*..

?me

l CORES 103- 0- - - -O CONTROL

# 0 DISCHARGE __

E a

P W I

/ --

1 0 *- __ i y) ; -- /

~~

M , __ /

< . -- /

E a ~

/

a -

,/ ~

~ '

- _ 16 CD (T

[

Z __

/

L1J __ /.

E -

10 '-

i g /

~~* __

. s

. Y 1

10 MkR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig. 14-1. Mean blomsse per meter equered or animele collected l In bottom core semples in the discharge and control beelne.

Given are mesne (c o nn e c t e d circles). etandard devietions (r e c t a n g l e s) . and rangee (h o r i z o n t a l b er e) .

I-57

CORES 5 x10 8- 0- - - -O CONTROL ANNELIDS e = DISCHARGE E

O .

f.O N .

CD __

_.J

<( --

3 __

O 1 94- ",- q

~

. <y ~-~

/

}\ --

)

s

\

/()y ,=

/

Q ~

s -

, /

Z g --

/

~ .

-4 --

~~

(r .

V y -- \ __

r - V D -

Z .

Z

<C W __

E 1 03-l .

1 5x102 MkR f9 JbN f9 SkP f9 DNC f9 SAMPLING PERIOD Fig.15. Mean abundence per meter equered of ennelide collected in bottom core semples la the control end discharge besine. Given are means (c o n n e c t e d elecles). standard devestions (r e c t a n g l e s and ranges (h o r i z o n t a l b er s) .

I-58

l l

CORES MOLLUSKS l 3500- o- - - -O e

CONTROL O DISCHARGE l

E 1

o l

M 3000-N .

cn

_J

< 2500- __

D O

a 2000- __

z __

W cn 1500-E '

q D <

s z /

/ ,

~T

z 1000- -- /

s o

/ /

4 --

/

w

/ ,

r / A s

/

e D

\ '

d C:[=/ = '

500- :

. ,r l

~

0 i MkRN9 JbN f9 SkPf9 DkC 79 SAMPLING PERIOD Fig. 15-1. Mean abundance per meter sguered of mollusks collected in bottom core semples in the control sad discharge beeine. Given are seene (c onn e c t e d c ir e t e s) . stenderd devietsen.

(r e c t a n g l e s) . and ranges (h o r i z o n t a l b er e) .

l I-59 l

s CORES 10000- o- - - -O e

CONTROL O DISCHARGE CRUSTACEANS E

g __

cn 8000- --

~

cn D

Q

> 6000-O Z

- / ,

x / \

LtJ l

\

Q 4000- ' \ P E __

/

\ /

3 I

\ /

Z --

/

\ /.

z __ / --

\__ /

i i 4 \

uJ 5 E 2000- ' ^ f

, h --

6 __

== __

d --% =m 0 -

l MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD rie. 15-2 n... .sona.... ,.c ..t.e .. .. 4 .r .ro.t...... ..ii..t.4 l In bottom core esmples in the control and discherge bssine.

I Given are means (c o nne c t e d c i r c l e s) . sienderd deviettons I (r e c t ang l e s) . and ranges (h o r i z .. . e l bere).

I-60

l l !

CORES 35- o- - - -O CONTROL 0 0 DISCHARGE ANNEllDS 30-e E

O in --

N O

v I

l CD (n

< 20-E O

m CD Z

< <t g ' \

E f '

10- s -

/ \ --

-- / '

_e s __

(f ,

cx --

-- ~ ,

T__ --

O --

m O

f --Hp

= "

0 I I E 1 1 I J MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig.16. Mean biomees per meter equered of ennetide cellected in betten core semples in the eeni al and discharge beelne. Caven are seene (c o nn e c t e d elects.). etandard devietions (rectanglee) l l

end eenges (h o e l t o n t a l b ac e) +

l I-61

The mean abundance for bottom cores is similar for both discharge and w

control basins during all four sampling periods, with the control basin having i

slightly higher means.

Total Animal Benthos '

The basic statistics for each taxon present in bottom core samples and venturi suction samples are given in Tables B-1 and B-2 of Appendix 2, res pectively. Included are the number of individuals mI with station means, standard deviations and ranges by taxon, basin and sampling period, and the mean wet and dry weights of each major grcup for each basin and sampling period.

l l

Species diversity and evenness have been calculated for each station both quarterly and annually and are given in Table B-3. The spectra of diversities for venturi and bottom core samples have been graphed against the four sampling periods in Figs.17A and 17B respectively, for the control and discharge basins. From these data it is apparent that the Shannon-Wiener species diversity index is greater in the control basin than in the discharge basin for all sampling periods regardless of the sampling technique. The evenness spectra, graphed in Fig. 18 show somewhat different results.

Although evenness is greater in the control basin than in the discharge basin throughout the year for the bottom core samples, evenness for the venturi samples is greater in the discharge basin during March and June.

I-62

CORES O---O CONTROL 0 0 DISCHARGE 4.00-

=

l 1;---_& -@

l 3.00- * --

=_ --

.= = A n-

== K

x c =

v 2 00- .. .

I-

- 1.00-en T B tu

> 0. 00-o VENTURIS O- - - -o CONTROL W 0 0 DISCHARGE

- 4.00-o ~

C --

LLJ " O --

O. p cn 3. 00- c,. _- &

,,= __- -

-0 wW

~~

= :. p 2.00- .

~~

%/ =

1.00-A 0.00 MkR $9 JUN f9 SNP N9 DNC $9 SAMPLING PERIOD Fig.17. Species diversity spectre of ben thie animals from vertuel semples (A) and bottom core semples (B) . Givon are means (c ennec t e d circ le s) . etandard deviettone (rectangleel and

=

ranges (h o r i z o n t a l bers). For each control spectrum n 5 for each discheese spectrum. n = 7 1

' I-63

w CORES O---o CONTROL e : ISCHARGE 1.00-

"* -E - -

0.80- --

-bI]

(F -

- - Mrb. "-

== , , _,

0.60- m

=

0.40-m 0.20-B m

w 0.00 W

i VENTURIS LLJ

> O- - - -C CONTROL

: IscHARGE w 1.00- :: -

{ r- _ _

0 80- c* ::- -

MN84; --

o

==

~~

=

0.60-0.40-1 0.20-A l

! 0.00 MkRN9 JbN f9 SkPf9 DbCf9 SAMPLING PERIOD Fig.18. Evenness spectre of benthie enirals (com venturi semples (A) and bottom core semples (B) . Given are meens (rectangles) and (conne c ted e le c l e s) . standard devietions = 5 for ranges (horizontal b er s) . For each control spectrum. n each discharge spectrum. n = 7.

I-64

Annel i_s_

The phylum Annelida collected in the venturi and bottom core samples for March, June, September and December 1979 is represented by 98 ta$a, of which 97 are polychaetes and one is an oligochaete (Table 1) . This represents a

. slight increase in the total number of taxa found in both 1977 and 1978 (each f

with 95 annelid taxa). Of these taxa, eighteen found in 1977 and/or 1978 were not found in 1979, while eight taxa were unique to 1979. However, in most instances the variations are caused by identifying a taxon to different taxonomic levels (i.e., in some instances a specimen in poor condition is identified to family, where otherwise it is identified to species; newly identified species may have been lumped under the family name in the past).

For 1979 a total of 91 taxa were found La the control basin, while the discharge basin had a total of 82. Seventy-five taxa were common to both l

basins.

Control l

The seasonal occurrence of the annelid taxa in control and discharge i samples is shown in Fig. 7A. As this graph pools all taxa occurring in 42 I

l discharge samples and 30 control samples for each sampling period, it is a good indication of the relative abundance of annelid taxa over the total areas encompassed by the control and discharge stations. Annelids found in the control basin showed only a slight seasonal variation in the number of taxa in the first three quarters of 1979. However, between September and December, there was an increase from 64 ta4a (the lowest number noted for the year) to l

l I-65

79 taxa (the highait .1 umber for the year) . This represents a 23% increase in s the number of taxa collected (Fig. 7A).

The percent contribution of annelids to total animal abundance in control bottom c' ore samples is shown in Fig. 6B. The March 1979 samples had the highest percent contribution (80%), while the other three sampling periods contributed approximately 60%.

While the percent contribution for control cores showed a sizeable drop from March to June (Fig. 6B), both mean abundance m' and mean biomass m" of annelids collected in bottom cores showed increases (Figs. 15 and 16). In September there was a fairly sizeable decline from June levels in both abundance and biomass (a decrease of 59% and 61%, respectively). A decline in annelid core biomass through the December sampling period occurred, while the 4

mean annelid abundance nearly equaled that of March, increasing by 89%.

Annelids collected in control venturi samples maintained a fairly constant contribution to total animal abundance in control samples 'of approximately 20%-

~

throughout the year (Fig. 6A) . The mean abundance m of venturi annelids exhibited a nearly constant increase in numbers during the four sampling periods with the numbers m' increasing 115% between March and December (Fig. 9). The mean annelid biomass showed a slight decrease f rom March to June. A general increase then occurred for the remainder of the year with the highest mean biomass noted in December (Fig.12B) .

l I-66

l Dischar ge The number of annelid taxa found in the discharge basin remained virtually unchanged in March, June and December (Fig. 7A). This number dropped 36% in September, however. Fig. 6B shows that the core annelids in the discharge basin constituted a much larger percentago to the total animal abundance than those of the control basin. The summer months showed a slight decline in their contribution, but it was generally quite high (nearly 80%) .

The mean biomass for bottom core annelids in the discharge basin was nearly constsht throughout the year, showing only a gradual decline from March through December (Fig.16) . As with the control basin, the mean abundance

~

m for the bottom cores in the discharge basin showed great fluctuations for the yc3r (Fig.15) . A 68% increase in abundance occurred between March and June; this was followed by another precipitous drop of 68% in September.

A dramatic increase of approximately 200% brought the December discharge abundance nearly to that found in the June bottom cores.

Fig. 6A eLows that the venturi annelids displayed a fairly consistent percent contribution to the total animal abundance in the discharge basin in March, June and December. In September, there was a noticeable drop to 154.

In December the percent contribution returned to 434. This fluctuation is reflected also in the mean annelid abundance (Fig. 9) and the mean annelid biomass (Fig.128) for discharge venturis. The abundance for the discharge basin (Fig. 9) increased 131% between March and June, dropped by 75% in September, and increased over 9004 in December. Likewise, the mean annelid l

I-67 1.

~

venturi biomass (Fig. 12B) dropped from 0.09 grams m in . Tune to 0.03 grams i in September, then increased sharply to 0.12 grams i (a 3004 increase) in December.

l Post-operational Trends: Annelids The total number of annelid taxa found in the control basin for the 12 quarterly sampling periods of 1977 through 1979 was (with one exception) always higher than the total number of taxa found in the discharge basin. The three years of sampling further showed that, in general, the number of taxa in ,

both the control and discharge basins declined from the first through the third sampling periods; this trend was generally followed by an increase in l

December.

With only slight exception the above trends appear to be in effect for both the annelid abundance and bicreass in both venturi and core samples collected in 1977 through 1979. In assessing the three year data for the discharge basin, it appears that the operation of Unit 3 has little effect on the annelid population. It appears that they follow the same seasonal fluctuations regardless of the operation of Unit 3.

Mollusks A total of 93 molluscan taxa, including 46 gastropods, 45 bivalves and two amphineurids, were collected during 1979 (Table 1) . Eighty-four taxa were collected in the control basin and 52 in the discharge basin. Forty, or I-68

l almost 50% of the 93 taxa collected were unique to the control basin, while eight taxa were found only in the discharge basin.

The percent contribution of molluscan taxa to total animal abundance is shown in Fig. 6A. Consistently more species were found in the control basin than in the discharge basin throughout 1979 (Fig. 7C). Exce;t for a slight increase in June, the number of control taxa remained relatively constant throughout the year. The number of taxa collected in the discharge basin was consistently about 50% of the number collected in the control basin. The discharge basin in March and June had an equal nunber of taxa present, followed by a slight decrease in the number of taxa in September. The number of molluscan taxa found in the discharge basin increased in December to 28.

This was the highest number of molluscan taxa found in the discharge basin in 1979.

~

Molluscan mean abundance m for venturi samples (Fig.10) was significantly higher in the control basin than in the discharge basin in March (0.02 0.50 ) . Control basin abundance was consistently around 100 individuals m~ with a moderate increase noted in September (Fig.10) . Discharge abundance remained consistently low throughout the year until the December sampling period, when it rose sharply to 52 individuals m' .

~

Molluscan mean abundance m in core control basin samples (Fig.15-1) exhibited a pattern nearly opposite to that seen in the venturi samples.

I-69

. I

l l

i l Where the venturi abundance decreased from March to June, increased in September and decreased again in December, the core abondance increased from

)

March to June, decreased in September and increased once again Ln December.

Dis.harge abundance in the cores follows the same pattern as in the core control abundance, but show differences in means between sampling periods.

I

~

The mean biomass m for mollusks in venturi samples from the control and discharge basins is presented in Fig.13. There is considerable variation in both control and di.e.-harge biomass data. The control biomass was apparently greater than discharge biomass for the first three sampling periods; this difference was significant only in June (0.001 < P < 0.002) .

However, in December the discharge biomass was greater than the control biomass. Both basins showed more than a ten fold increase in biomans from June to September. This was followed by a corresponding tenfold decrease in December in the control basin, while the biomass in the discharge basin renuined equivalent with September.

~

Post-operational Trends: Mollusks

The number of molluscan taxa found and their abundance has been consistently higher in the control basin than in the discharge basin during all sampling periods of 1977 through 1979. Also for all three years the number of polluscan taxa found only in the control baain has always been higher than the number of taxa found only in the discharge basin. In 1977 more than half of the molluscan taxa were unique to the control basin.

Molluscan biomass has been consistently lower in the discharge basin than in I-70

1 I

l l

l the control basin for all post-operational sampling periods except December 1979.

Crustaceans The benthic samplea of 1979 contained a total of 107 taxa of crustaceans (Table 1). Nine*y--seven taxa were collected in the control basin and 75 taxa were collected in the discharge basin. Thirty-two taxa were unique to the control basin, while ten were found only in the discharge basin. The percent contribution of crustaceans to total animal abundance in venturi samples is presented in Fig. 6A. The number of taxa found during the different sampling periods of 1979 varied by 15% in the control basin, and by 23% in the l

discharge basin, there were always more taxa in the control basin than in the discharge basin (Fig. 7B). Most of the taxa that occur in both basins are more widely distributed in the control basin (Table 1).

-2 Mean abundance m of crustaceans in venturi samples increased from March through December for both the control and discharge basins (Fig.11).

Significant differences between the control and discharge means were detected for the first (0.01 < P < 0.02) and second (0.01 < P < 0.02) quar ters (Table B-7, Append ix B) . Although there appears to be a greater difference between the control and discharge means in the four th than in any other quarter, the variation in control data for that period is so great that a significant I difference could not be detected (0.2 < P < 0.5).

I-71

~

Crustacean abundance m followed quite a different pattern in the core samples (Fig. 15-2) . The control data reflect the seasonal trendr observed 3 for annelids (Fig.14), but the discharge data are constant for March,

~

September and December at between 745 and 840 individuals m , with a

~

dramatic increase to 2066 individuals m in June.

Mean biomass m" in venturi samples decreased slightly between March and September in the control basin (Fig.12A), then increased to above the March mean in December. The discharge biomass was essentially the same for March and June, then rose to a high in December. The control and discharge mean biomass did not differ significantly for any sampling period (Table B-7, Appendix B).

Post-operational Trends: Crustaceans The crustacean venturi abundance and the total benthic number of species in the control basin have varied with a wavelike regularity over the three years of the post-operational study. There was a consistent rise in the above l

two parameters during 1977. This rise reached a plateau in March 1978 for number of species and in June 1978 for abundance, after which a steady decrease in both parameters was observed. The decrease in number of species reached a low in December 1978, and began to rise again in March 1979, preceeding by one quarter the same pattern for abundance. The number of species reached a plateau in September 1979, and decreased somewhat in j

~

December. The mean abundance m reached its highest 1979 level in l

December . If the above pattern is to be continued during the upcoming year, I-72

the decrease in number of species during December 1979 should continue through June or September 1980, and should also result in a gradual decrease in the number of individuals beginning in Purch 1980.

The discharge basin shows no clear trends over the three year post-operational study period. The variation that does occur, however, is on a more depressed scale than that seen in the control basin. The difference between the largest an._ smallest mean number of individuals in control venturi samples over the three year period is 125, compared with a difference of 70 individuals for the discharge basin 43 ring the same period.

There are many differences in the distribution of crustacean f auna between the control and discharge basins. Table 1 shows that most taxa occurring in both basins are more widely distributed in the control than in the discharge basin. This can be considered to indicate the unsuitability of certain areas in the discharge basin for many crustacean species, for the following reason.

Any species that is capable of living in a large percentage of the control basin stations is neccessarily not limited to narrow habitat requirements, ,

i because the control basin offers a wide variety of habitats, in a rough i zonation related to distance from shore. These habitats include muddy bottom dominated by seagrass, muddy bottom without rooted vegetation, rocky bottom with attached seagrasses and macroalgae and bare, rocky bottom / submerged i

oyster reef. In contrast, the discharge basin at the sample stations offers bare mud bottom, mud bottom with rooted seagrass and, occasionally, mud covered rock / oyster bottom. The rather narrow habitat range offered by the l

discharge basin should, therefore, offer to those species capable of living in I 1-73 w

such an environment a larger area of pctential habitat tha, does the control basin. This not being the case indicates that some factor (s) other than substrate and vegetation type are affecting distribution within the discharge basin.

A good example of this condition is provided by the ampeliscid amphipods, tich are commcnly found in shallow water muddy bottom environments along the middle west coast of Florida. That these typically muddy bottom amphipods are found at only 50% of the stations in an area dominated by muddy bottom (Table

1) indicates that some factor other than substrate type prevents its occurrence there.

Other Groups The other groups are those taxa other than annelids, crustaceans, and mollusks collected in the core and venturi samples. Since larger animals are sampled more effectively using the venturi suction method and smaller animals are sampled more eff ectively using the bottom core method, only those data from the more effective method of sampling are used for comparisons made in this section. Data from the venturi suction samples thus are included for echinoderms, tunicates, fishes and sponges, while bottom core data are used for nematodes, nemerteans, platyhelminths and sipunculids. Relative occurrences are given for these groups in Table 1.

Relative occurence is always greater in the control basin with the exception of chaetognaths and coelenterates which are roughly equivalent for both basins. Ascidians were not found in the discharge basin in 1979.

I-74

~

i

Biomass data for the other groups is presented by sampling period in Table

4. Generally all groups had a lower biomass in the discharge basin than in the control basin. A major exception is the biomass for the fourth quarter Porifera, which is greater in the discharge basin.

Post-operational Trends: Other Groups l

Comparisons of 1979 other groups results with 1977 and 1978 data indicate some differences between the control and discharge basins. Relative occurrence, with the exception of chaetognaths and coelenterates, is always greater in the control basin than in the discharge basin. Chaetognaths and coelenterates occurence is minimal and roughly equivalent for both basins.

l In general, biomass follows the pattern of relative abundance, with the control basin having consistently higher biomass values than the discharge basin. An exception to this is the poriferan biomass in December 1979, which is greater in the discharge basin than bs the control basin. This is also the first time any sponge has been collected in a ventur.t sample in the discharge basin during the three years of study.

Post-operational Trends: Ben th ic An imals Mean annual biorass and abundance for 1977, 1978 and 1979 are compared for control and discharge basins in Tables 5 and 6, respectively. Venturi control basin abundance and biomass consistently exceed the discharge basin abundancee and biomass. Core biomass was always greater in the control basin than in the I-75

Table 4. Mean biomass (grams dry weight) m-2 of major benthic groups other than annelids, arthropods and mollusks in control and discharge basins during differet.t sampling periods of 1979. (Data based on venturi suction samples for echinoderms, ascidians, fishes, and sponges, and on bottan core samples for nematodes, nemetteans, platyhelminths, sipunculide, coelenterates, and chaetognaths.)

MAR JUN SEP DEC Taxcn Con Dis Con Dis Con Dis Con Dis Echinodermata 0.8519 0.0529 1.8591 0.3576 0.9619 0.0772 0.9789 0.0054 Ascidiacea 4.9489 0 1.9884 0 1.3440 0 0.2794 0 Osteichthyes 0.6727 0.1612 0.4956 0.1964 0.2810 0.0531 0.2150 0.1517 Porifera 4.5548 0 1.2668 0 1.5924 0 2.1391 5.2151 Nematoda 0 0 0.0071 0 0.0020 0 0.0382 0.0015 b Nemertinea 0.0306 0.0538 0.0300 0.0044 0.0173 0 0.1961 0 as Platyhelminthes 0.0102 0 0.0010 0.0025 0 0 0.0306 0 Sipunculida 0.1131 0.0797 0.0413 0.0022 0.13'.9 0 1.3904 0 Coelenterata 0 0.2023 0.0519 0 0 0 0 0 Chsetognatha 0 0 0 0 0 0.0091 0 0

~)

3 Table 5. Annual mean biomass (g ar2 except zooplankton, g mF ) for control and discharge basins, 1977, 1978 and 1979.

1977 1978 1979 Sample Discharge Control Discharge Control Discharge Type Control Seagrasses dry wt. 12.38 22.40 26.50 439.52 2.28 57.28 Macroalgae dry wt. 24.78 0.68 477.95 1.98 68.60 0 Benthic f auna Core samples 38.37 6.43 12.17 4.77 77.50 10.46 7 dry wt.

U Venturi samples 46.53 2.42 35.80 8.17 41.44 15.47 dry wt.

Oysters, Oyster reefs 79.68 31.50 113.99 60.04 178.41 57.95 meat dry wt.

Spat, Oyster reefs 54.94 49.33 144.49 29.85 253.94 47.59 meat dry st. .

Zooplankton 0.0877 0.0518 0.1190 0.0567 0.0875 0.1121 dry wt.

9

Table 6. Annual mean abundance of individuals m-2 (zooplankton n-3) for control and discharge basins, 1977, 1978 and 1979.

Sample 1977 1978 1979 Type Control Discharge Control Dischstge Control Discharge Benthic fauna core samples 20,852 7,662 3,475 5,599 12,650 8,853 Venturi samples 388 53 409 79 333 98 Oysters, Oyster reefs 560 315 1,018 465 1,470 445 Spat, Oyster reefs 302 194 664 176 1,614 305 Zooplan kton 8,127 23,048 8,347 15,117 19,221 19,346

-)

discharge basin, but the discharge basin had a greater number of individuals than the control basin in 1978.

Fig.19 displays core and venturi quarterly mean abundance for 1977, 1978 and 1979. Venturi abundance in the control basin is always higher than abundance in the discharge basin. Venturi control basin abundance exhibits a fairly regular pattern of variation, suggesting that the abundance levels of the benthic communities in the basin are fluctuating in a two-year cycle. The discharge basin shows much less variation in abundance than the control basin, and there is no clear pattern of variation.

Core abundance (Fig. 19) is usually higher in the control basin than in the discharge basin. This was not the case in March 1977, when they were practically equal, and in September 1978, when core abundance was higher in the discharge basin. As in the venturi samples, core control abundance showed greater variation than discharge abundance.

Figures 19-1 and 20 present quarterly means for divers,ity and evenness for, venturi and core samples during 1977,1978 and 1979. ' These two figures replace Table 12B of the 1978 Final Report. Diversity (Shannon-Wiener Index) is consistently higher in the control basin than in the discharge basin for l

Differences between basins were both venturi and core samples (Fig.19-1).

greatest in 1977 and least in 1978 and early 1979. In late 1979 it appears that control and discharge diversity values were again diverging. Over the l

l course of this study, it is the discharge basin diversity that is fluctuating; control basin diversity has remained fairly stable at a value of approximately l

I-79

600- G- - - --O

=

CONTROL

= OiSCnARoe _ ABUNDANCE VENTURI a , * '

'N U) 500- - N s ,O N 400- f \ &'

/ '

W 300- .e-a

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s o.

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'y' 4 DISCnARGE g

E 10' ' . . . > i . . i MAR 77 JUN 77 SEP 77 DEC 77 MAR 78 JUN 78 SEP 78 DEC 78 MAR.79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig. 19. Mean benthic animel abundance in venture and betten core semples for the guerterly t

sempling periods of 1977. 1978. and 1979

4.50- DIVERSITY VENTURI COnTR0t 4,00 ?---O

- - DISCHARGE 3.50- -O

-G- ' ,e.

'v4 s G.

~

, b - .g. -e *

^ 3.00- 'sE s' s

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~ 3.50- 0- ' .G* e - - -e.

c e ~~ 's -O

s D - - -e- - - -0 '

3.00- 'e '

2.50-2.00- _

1.50 , , ,

APR 77 JUN 77 SEP 77 DEC 77 NAR 78 JUN 78 SEP 78 DEC 78 MAR 79 JUN 79 SEP 79 DEC 79 SAMPLIS& PERIOD flg.19-1. Mean benthic entmel diverst i y (H) in venture and bottom core semples for guerterly sempling periods of 1977. 1978 and 19/9.

~

EVENNESS VENTURI e- - - -o C0n rR0t.

0.95- e--- --e DISCHARGE 0.90- -

0.85- ,A

' \

n e - - -o

-e o 0.80- & N , -G, , * -

- w- s ,A s ,

y) 0.75- 's /

' 's cf ' - O U)0.70

- w -

CORES h 5W95-

0. e- --- - -O 0

CONTROL 0 DISCHARGE

> 0. 90-0.85-0.80- * -6 e.

-o

'% -G.

0.75- * ~ 's 'y ' ~ 4 ' ' '9- - #

l - -

0.70- 0 0.65- -

0.60- ~

0.55 , , , , , , , , , , , ,

APR 77 JUN 77 SEP 77 DEC 77 MAR 78 JUN 78 SEP 78 DEC 78 MAR ,79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig.20. Mean benthic animal evennese (e) in venture end core semplee for guerterly eemplans periods of 1977. 1978 and 1979.

._)

3.0 while discharge basin diversity values have fluctuated between 1.7 and 2.8. Venturi and core sample diversities follow similaz patterns in each of the two basins.

Evenness data for core samples during 1977, 1978 and 1979 (Fig. 20) follow the same general pattern as diversity, that is, control basin evenness consistently exceeds discharge basin evenness. In the venturi samples, discharge basin evenness exceeded control basin evenness throughout 1978 and during the first two quarters of 1979, but dipped to lower levels in late 1979.

Compar isons With Pre-operational Data: Benthic Animals Comparisons among pre-operational, 1977, 1978 and 1979 venturi samples for control and discharge basins are shom in Fig. 21. This figure includes data from Tables 17A and 17B of the 1978 Final Report. T-tests (Table B-7, Appendix B) reveal that in 1979, as in 1977 and in 1978, control venturi abundance and biomass were significantly greater than those measured in the pre-operational study. The dramatic increase in control venturi abundance and biomass that was noted between the pre-operational study and 1977 has been maintained during 1978 and 1979. No major change has been detected in either abundance or biomass in control venturi samples since 1977.

A steady increase is seen in both meaa venturi abundance and biomass in the discharge basin since 1977. Discharge venturi abundance and biomass in 1977 were not significantly different from pre-operational values, but in 1979, as in 1978, they are significantly greater (see T-tests, Table B-7, Appendix 0) .

I-83

r VENTUR1 O o- - - -o CONTROL

ISCHARGE M 600- __

N 500- --

T __

W -*~~,

cn 400- w -

r /

/--

s

'1) 3 z 300-f

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z 200- i

< /

w '

w r 100- 3E r-B I _r_ __

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r 0- - - -o CONTROL o DISCHARGE O

N 100-o 80-O .

Ch r 60- --

O 9, '

' o G 40- ,'

~

/ --

Z /

< 20- /

a 0 : - --

Pf1E-bP i977 k97h i97h SAMPLING PERIOD Fis.21. Overall benthie eommunity bsomess (A) and abundenee (B) per notee sguseod from ventwei sempise fee conteel end dio charge besine for pre operational. 1977. 1978 ead 1979 studies. Given are means (c o nn e c t e d elecles) and 95% confidence limits i (h o r i z o n t e l b ec e) .

I I-84 l

Fig. 22 shows temperature and salinity data for both basins for all four sampling periods. Data from Tables 17A and 17B of the 1978 Final Report are included in this figure. Temperature and salinity did not differ significantly from pre-operational values in 1977 or 1978 in either basin (see Final Report 1978, p. I-151) . In 1979, temperature and salinity in the discharge basin likewise showed no significant differences from pre-operational values (see Table B-7, Appendix B) . In the control basin salinity showed no significant departure from pre-operational values, but {

temperature dropped significantly (P < 0.05) in the control basin. !

l I

Figs. 23 through 26 show a range of abundance and biomass that encompasses two standard deviations above and below the 1979 quarterly means ir. control and discharge venturi samples. Superimposed on these are the corresponding quarterly means from the pre-operational study. All pre-operational means fall within two standard deviations of the 1979 means.

I I-85

G TEMPERATURE

&---O CONTROL

: DISCHARGE w 35-D s __

< 30-W l~ --

N ~~ y A, - >

O_ -

r 25- - *-- -* ' _

_- s -

g __

s,

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15

- SALINITY l-O_ O- - - -C CONTROL DISCHARCE Q_

- 35-6--

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z __

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< 25- l l

Cn --

z I' -;____4,.

- d.

< 20-g __

E A 15

PRE-bP $977 k97d $~5I9 ,

1 l SAMPLING PERIOD !

I Fig.22. Overall salinity (A) and tempereture (B) for control l l end diebseine for pre operetienei. 1977. 1978 and 1979 studies.

l Civen see means (c o nn e c t e d careles) and 95% confidence limits I (hseizontal b er e) .

1-86

VENTURI 1300- c j 12'OF 1979 ME ANS CONTROL BASIN e- - - -4 PRE-OP MEAN r;

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in 1000-4 J

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0 9 9

9 9 MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD F:g.23. M - seanoence per sgance setse (ces sentari contres sempies of the pre operetienes stao/ saper:aposso over tso stancaro ceristions of the compereble asen from tne 1979 slad/.

I-87

VENTURI 800-

$ $ s2"or is79 ucANs otscsARcE bas!N j g 0---4 PRE-OP MEAN O

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T I T MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fis.24. Meen abundance pee meter seusee frem venturi discheese samplee of the pre operstlenal study supeelmposed over two slendsed devistlene of the compeceble meen from the 1979 etudy.

I-88

l VENTURI 1

500- L j 2 z'OF 1979 MEANS CONTROL BASIN 0---e PRE-OP MEAN m

E 400- ".

o (A

N o

v l (n 300-l M E -

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^

100- L

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MAR 79 JUN 79 SEP 79 DEC 79 l SAMPLING PERIOD Fis.25. Mean 61...., pee eguare . t.e reen eentwei eente.I es=,les of the pre operational study superimposed over two standard devietions of the compaesble meen (com the 1979 study.

I-89

VENTURI 175- E i 2'oF 1979 MEANS DISCHARGE BASlH

e. - - 4 PRE-OP MEAN 150-n :i _

E ;

4 1

o M

. 1 N 125- i O a v ..

f' m

m 100-

< .i E - ,' .i o .

m 75-z .

4 .-,.

g +

E 50-

.+

M 4

25-l g____p ___p-----lt

, t1AR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fis.26 M e e .. blemens pee egvere meter from ventues discheese semples of the pre operetional etudy espeelmpossd ovoc two i

standsed devtottens of the compecable meso from the 1979 study.

I-90 l

l

Seagrass and Macroalgae Macroalgae Sixteen genera of macroalgae were collected from all sampling stations in the control and discharge basins during 1979. Fifteen genera were found exclusively in the control basin. Digenia sp., collected in both the control and discharge basins, was the only genus of macroalgae found in the discharge basin during 1979 (Table 1) .

-2 The biomass m of macroalgaa collected in the control and discharge basins during 1979 is presented in Table 7. With the exception of one sample of Digenia collected in June, no macroalgae sere found in the discharge basin during 1979. However, a considerable increase in macroalgae biomass over March levels was recorded during June and September in the control basin.

This was followed by a sharp reduction in biomass prior to the December sampling period. Control basin macroalgae biomass for 1979, peaked in September, with the lowest biomass recorded for March.

Seagrasses A total of four species of seagrasses were collected from all sampling stations during 1979. These were Halodule beaudettei, Halophila engelmanii, Ruppia maritima and Syringodium filiforme (Table 1) . All four species were found in the control basin, while the discharge basin contained only Halodule i

l I-91 l

l .

Table 7. Biomass (grams dry weight) m-2 of seagrasses (SG) and macroalgae (MA) at discharge (D) and control (C) stations during different sampling periods of 1979.

S ta tion MAR JUN SEP DEC Marber SG MA SG MA SG MA SG MA 1C 3.7 44.1 0.4 10.7 0 160.5 0 46.2 2C 0 3.2 0 102.0 0 256.8 0 44.7 3C 19.9 6.1 0.5 181.0 0 41.4 4.7 2.1 4C 0 55.1 0.2 156.5 0 37.3 0 0 SC 0 18.9 13.3 14.5 0 56.8 2.3 134.0 Control Mean 4.7 25.5 2.9 92.9 0 110.6 1.4 45.4 1D 0 0 0 0 0 0 0.5 0 2D 68.8 0 101.3 0 64.7 0 19.1 0 3D 101.4 0 218.8 0 134.6 0 -0 0 4D 153.1 0 53.3 0 167.6 0 30.1 0 5D 87.3 0 110.0 0.4 169.3 0 67.3 0 6D 34.1 0 0.1 0 0 0 0 0 7D r. 0 0 0 0 0 0 0 Discharge Mean 63.5 0 69.1 0.1 76.6 0 19.9 0 I-92 1

l

beaudettei. Thalassia testudinum, collected in the control basin d 2 ring 1978, was not observed in 1979.

Control basin seagrass mean biomass declined steadily from March through the spring and summer 1979 quarterly sampling periods (Table 7). No seagrasses were found in the control basin during September, but a very slight increase in biomass was recorded during December. Halodule beaudettei biomass remained relatively unchanged in the discharge basin during the first three quarters.. There was a considerable decrease in H. beaudettei bioma'ss, however , during December.

Data on seagrassee and macroalgae were combined to give total macrophyte 2

biomass. Mean macrophyte biomass m7 , standard deviations and ranges for each quarter and basin are shown in Fig. 27. Control basin macrophyte biomass was generally greater than discharge t sin bioms.: except during March 1979.

Mean seagrass idaf lengths, their standard deviations and ranges were calculated for each species in both tasins (Fig. 28). There was a general increase in Halodule beaudettei leaf length in the control and discharge basins from March to June 1979. H. Jeaudettei leaf length declined very gradually during September and DecemSer in the 61scharge basing H. beaudettei was not collected in the control bayin during this same period. Ruppia marittma and Syringodium filiforme Liso exhibited a spring increase in mean leaf length. S. filiforme leaf length declined gradually throughout the remainder of the year, while Ruppia maritima disappeared. Halophila engelmanii was found only in the control basin during March.

I-93 l

l l

i l

MACROPHYTES l

l 300- &---O CONTROL e

0 0 DISCHARGE E

l O M __

N o 250-v M __

M r 200-o CD --

W __

H --

> 150- --

I _

O_

O --

Cr O '

- R'

< 100- ("

r -

s

\

Z / ---4( \

< y ---4>-

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E ~~

50- ,

g3 l (I \ '

__ h 0 --

l MkR 79 JbN 79 SkP 79 DEC 79 SAMPLING PERIOD Fig.27. Mesn macroph i te biome . per sgusee meter in the i dischsege and control beelns. Given see means (c o n n e c t e d

! eteelse). standeed devastiens (cettengles) and eengee thee ental (

b ec e) . l I-94 t

I

i l

4 i

l

)

SEAGRASSES (EXCL. HALODULE)

CONTROL (3- - - -c) RUPPIA h . - .-A HALOPHILA 40- BgN e . --- -e SYRINGODIUM 35-30- --

^ 25-E _

O 20- __

15- u ' '

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H 10- a n~ . - .. ~ .c o -

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$25- __

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15- -

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~~

10- -

e No l

< a ::s s --

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MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD l rig.28 noen iner rength (besed on no.ber er o . ,,,ncee) roe l the eengree. HALODULE in the control and diecherge besine (A) and ror the eengressee RUPPI A. HALOPHIL A and SYRINGODIUM in the control beein (B) . Given are meone (c o nn o c t o d erebele), etendard l devietions (r e c t a ng t o :) and rangee (h o r i z o n t a l b a r e) .

I-95

l Post-operational Trends: Macroa lgae_

l The most frequently observed macrcalgae genera in 1979 as well as in 1978 I

were Caulerpa sp., Gracilaria sp. and Sargassum sp.. Gracilaria sp., Caulerpa sp. and Spyridia sp. showed increases in relative occurrence of approximately 50% in 1979 compared to 1978. The relative occurrence of most sacroalgse I genera, however, declined during 1979 (Table 1).

Comparisons With Pre-operational Data Macrophy tes Comparisons of mean seagrass, macroalgae and total macrophyte biomass

~

m by basin and seasonal period are shown in Table 8 and Fig. 28-1. There was very little difference in total macrophyte biomass between the pre-operational (van Tine,1974) and 1977 studies in either basin. However,

~

total mean macrophyte biomass m was usually greater in both basins in 1978 and 1979 sampling periods compared to the same sampling periods in the pre-operational and 1977 studies (Table 8 and Fig. 28-LA).

Seagrasses have shown generally a net increase in olomiss over the years in the discharge basin, and a net decrease over time in the control basin (Fig. 28-1B and Table 8). Macroalgae have essentially vanished from the inner discharge basin, and have shown, beginning in 1978, evidence of a seasonal cycle of growth and dieback in the control basin (Fig. 28-lC and Table 8).

The overall macrophyte composition of the control and discharge basins has changed dramatically. During the pre-opecational study, the control basin I-96

Table 8. Mean a:acrophyte biomass (g dry wt.) m-2 by taxon, sampling period *, and basin for pre-operational and post-operational (1977,1978,1979) studies.

Sampling Control Basin Discharge Basin Taxon Period Pre-op 1977 1978 1979 Pre-op 1977 1978 1979 To tal 1 59 .5 50.8 108.7 30.2 25.3 21.1 25.0 63.5 Macrophy tes 2 60.2 59.5 78.3 95.8 44.1 58.0 45.2 69.1 3 --

49.1 164.0 110.6 4.3 9.5 142.5 76.6 4 42.5 34.3 53.9 46.8 16.1 11.6 39.6 16.7 Annual 50.2 48.4 101.2 70.8 20.1 25.0 63.1 56.5 Tota l 1 17.3 15.0 6.9 4.7 20.8 18.4 24.9 63.5 2 21.1 18.8 10.4 2.9 37 .4 58.0 44.1 69.1 7 Seag rasses 4.4 4.3 142.5 76.6 y

3 -- 12.7 0 9.5 4 12.7 20.8 0.8 1.4 11.2 11.6 39.6 16.7 Annual 15.4 16.8 5.6 2.3 15.4 24.4 62.8 56.5 To tal 1 42.4 35.8 101.8 25.5 4.5 2.7 0.1 0 Macroalgae 2 38.9 40.6 67.9 92.9 6.7 0.0 1.1 0.1 3 --

36.5 159.6 110.6 0.1 0.0 0.0 0 4 29.7 13.5 53.1 45.4 4.9 0.0 0.0 0 Annual -

34.8 31.6 95.6 68.6 4.7 0.7 0.3 0 4

Table 8. (Con t. )

Sampling Control Basin Discharge Basin Taxon Period P re -op 1977 1978 1979 Pre-op 1977 1978 1979 Rhodophy ta 1 32.2 25.9 56.0 7.4 4.4 1.0 0.0 0 2 17.1 24.5 16.0 60.2 4.2 0.0 1.1 0 3 --

11.0 0.1 11.5 0.1 0.0 0.0 0 4 15.7 3.2 6.4 4.0 0.5 0.0 0.0 0 Annual 20.8 16.1 19.6 20.8 1.5 0.3 0.3 0 rhaeophy ta 1 6.9 3.3 30.3 7.9 0.1 1.8 0.01 0 2 6.4 5.4 42.8 13.5 0.7 0.0 0.0 0 g 3 --

20.2 0.0 12.6 (0.2) 0.0 0.0 0 1

4 12.2 6.0 45.8 9.1 8.5 0.0 0.0 0

$ Annual 9.8 8.7 29.7 10.8 2.8 0.4 0.0 0 Chlorophy ta 1 3.2 6.6 15.5 10.2 0.0 0.0 0.02 0 2 14.6 10.8 9.1 19.2 2.4 0.0 0.0 0.1 3 --

5.3 159.4 86.5 0.0 0.0 0.0 0 4 1.9 4.3 1.0 32.3 0.0 0.0 0.0 0 Annual 4.2 6.8 46.3 37.0 0.3 0.0 0.0 0

Sampling Periods 1, 2, 3, 4 correspond to pre-op samples of spring, suminer, fall, winter of 1973-1974, 1977 samples of April, June, September, December and 1978 and 1979 samples of March, June, September, December.

O

200- g--- ; g7gcgggGE MACROPHYTES TOTAL MACR 0 ALGAE 150- f 9

- / \ C E 100- ,a. f g-

, 'd - s O 50- f h s / b

e. ._ g ,_#_,

s o = = = ~ = = = 4 : = = = = = = =

o'S-7 - 1 8?lcljkog TOTAL SEAGRASSES O 100-m B

- < - r i E 50-

O ~ ' ~

~

- A - "

P-+-+- c -n- - ^ -c -e

[ 0 200- g - - g 0ggcgggGE TOTAL MACROPHYTES z S

< 150- /

f \

LtJ A E 300 As / \

p. 4

/ M \ ,- =\

' s

O-

' b 50-

. , 1 . . . r . .

1-73 2-73 3-73 4-73 1-77 2-77 3-77 4-77 l-78 2-78 3-78 4-78 l-79 2-79 3-79 4-79 SAMPLING PERIOD (O T Ps- Y R)

Fig. 28-1 Mean macrophyto biomese per meter equered for totel mecrophytee (A). total seegresses (B) . and total macroelgee (C) for guerterly sempting persede of the proeperettenel (1973). 1977. 1978. and 1979 studies.

p

batal macrophyte biomass was composed of 69% macroalgae and 314 seagrasses.

In 1977, the basin remained relatively unchanged. In 1978, however, the total sacrophyte biomass for the control basin was 94% macroalgae and only 64 seag ra s ses. By 1979, the control basin was composed of 974 nacroalgae and only 34 seagrasses ' Fig. 29).

A different pattern of macrophyte change occurred in the discharge basin.

During the pre-operational study, total macrophyte biomass consisted of 774 seagrass and 234 macroalgae. By 1977, although there was little cha'nge in annual mean macrophyte biomass, seagrass accounted f or more than 98% of the total macrophyte biomass. In 1978 the total macrophyte biomass for the discharge basin was more than 994 seagrass; by 1979 seagrasses accounted for 100% of the total macrophyte biomass. This dominance of the macrophytes in the discharge basin was due to the almost exclusive presence of one species, Halodule beaudettel (Table 1) .

Mean macrophyte divers (ty was calculated to give the number of species (or genera) m' in order to compare with p;e-operational data (Table 9). There was very little obvious difference in mean seagrass diversity in the discharge basir between the pre-operational and 1977, 1978, and 1979 studies. However, mean sacroalgae diversity in the discharge basin decreased from 0.6 for the pre-Op study to zero in the 1979 study. Mean annual seagrass and macroalgae diversity cecreased slightly in the csntrol basin, however, between the pre-operational ano 1979 studies.

I-100

M f""" """1 SEAGRASS MACROPHYTES DISCHARGE BASIN M nmuG MACROALGAE

< sen sun rn viu sen sun rn viu sen sun rn viu sen sun rn via

.n0-iU Fox... '

..... r. ..

..... C.....

O [. ...

75_ ......... . .... ., .....

CD ..

50- .. ...... ..... ..... ... .... ..... ..... .. ..... ..... .....

O p__

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25-Z .

O

^^^ ^ ^^^^ ^^-- -- ^^^- --- ^^-- -^ ----

^^ ^ - ^^ ^ ---

S c::.:::: :::1 SEAGRASS CONTROL BASIN o nuumu MACROALGAE

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- , N N 'N z 75- '

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i t

PRE-OP 1977 1978 1979 SAMPLING PERIOD Fig.29. Percent contributten of seegress and macrealgae to tetel meccephyte bsenese in the centeel beein (A) and the discharge basin (8) .

Table 9. Mean diversity

by taxon, samplf.ng period ** and basin for pre-operational, 1977, 1978 and 1979 studies.

Sampling Control Basin Discharge Basin Ta xon Period Pre-op 1977 1978 1979 Pre-op 1977 1978 1979 Total 1 6.0 7.4 8.2 5.6 1.9 1.4 1.3 0.7 Macrophy tes 2 7.8 6.4 4.0 5.2 1.5 0.7 1.0 0.8 3 -- 5.0 1.6 2.6 0.5 0.7 0.7 0.6 4 7.5 5.6 4.6 4.0 1.3 0.8 0.6 0.6 Annual 7.1 6.3 4.6 4.35 1.3 0.9 0.9 0.67 Total 1 1.3 1.6 1.0 1.0 0.9 0.6 0.7 0.7 Seagrasses 2 2.1 1.0 1.0 1.2 0.7 0.7 0.7 0.7 3 --

1.2 0.8 0.2 0.4 0.7 0.7 0.6 4 1.9 1.0 1.4 0.4 0.7 0.8 0.6 0.6 Annual 1.8 1.2 1.0 0.7 0.7 0.6 0.7 0.6 Total 1 4.7 5.8 7.2 4.6 1.0 0.9 0.6 0.0 Macroalgae 2 5.6 5.4 3.0 4.0 0.8 0.0 0.3 0.1 3 --

4.6 0.8 2.4 0.2 0.0 0.0 0.0 4 5.6 4.6 3.2 3.6 0.6 0.1 0.0 0.0 Annual 5.3 5.1 3.5 3.65 0.6 0.3 0.2 0.0 Rhodophy ta 1 2.8 4.2 4.6 2.4 0.8 0.6 0.1 0.0 2 4.3 2.6 1.4 2.6 0.7 0.0 0.3 0.0 3 -- 2.8 0.2 0.8 0.2 0.0 0.0 0.0 4 3.6 2.4 1.4 2.2 0.3 0.1 0.0 0.0 Annual 3.5 3.0 1.9 2.0 0.4 0.3 0.1 0.0 Phaeophy ta 1 0.6 0.4 1.8 1.2 0.1 0.2 0.3 0.0 2 0.5 0.8 0.6 0.6 0.0 0.0 0.0 0.0 3 --

0.4 0.0 0.6 0.0 0.0 0.0 0.0 4 0.9 0.6 1.4 0.8 0.0 0.0 0.0 0.0 Annual 0.8 0.6 1.0 0.8 0.2 0.1 0.1 0.0 -

Chlorophy ta 1 1.3 1.2 0.8 1.0 0.1 0.2 0.1 0.0 2 0.9 2.0 1.0 0.8 0.1 0.0 0.0 0.1 3 --

1.4 0.6 1.0 0.0 0.0 0.0 0.0 4 1.1 1.6 0.4 0.6 0.0 0.0 0.0 0.0 Annual 1.1 1.6 0.7 0.8 0.0 0.1 0.0 0.0

Number of species m-2 except number of genera m-2 for macroalgae of 1977, 1978 and 1979 studies.

- Sampling periods 1, 2, 3, 4 correspond to pre-op periods of spring, summer, fall, winter of 1973-1974; April, June, September, December 1977; March, June, September, and December 1978 and 1979.

1-102

i l

l l

1 l

Seagrass Monitoring Inside Radials The meat percent cover of seagrasses for the two inside control radials and the three discharge radials is presented in Table 10. The locations o.

these radials are shown in Fig. 2. Seagrass cover in the control area appeared to be randomly distributed over distance and time. The percent cover vas generally low with numerous dense patches found throughout the area. In contrast, seagrass cover for the discharge radials IDA and 2DA was generally dense throughout the year. Within the discharge basin, radial 3DA, which is nearest to and runs parallel with the discharge canal, showed the most sparse cover with bare patches randomly distributed over distance and time.

Distribution and cover maps for Halophila engelmanii, Ruppia maritima, Syringodium filiforme, Halodule beaudettei, Thalassia testudinum and total seagrasses for each quarter in the control basin are presented in Figs. 30 through 49. Two widely separated, sparse patches of Thalassia were found in March (Fig. 34). Thalassia did not occur during the remaining sampling periods. Ruppia and Halodule were scattered throughout the control basin during all sampling periods. Their distribution was greatest in June (Figs.

37 and 39); in cor.trast, in December their distribution was least, when only one otation with less than 5% cover was recorded for each 7pecies (Figs. 46 and 48). Halopb.3a was widely distributed throughout the basin in March, June and December, but cover was never more than St at any station. Halophila was not found in September. Syringodium was the most prevalent seagrass in the l

l 1-103

l l

( Table 10. Mean percent cover of seagrasses m-2 along two inside control radials and three inside discharge radials for the different sampling periods of 1979.

l Kilometers Control from ICA 2CA l Origin Mar Jun Sep Dec Mar Jun Sep Dec l 0.0 8.0 96.0 19.6 58.8 8.0 96.0 19.6 58.8 i 0.1 1.0 0 0.8 33.6 2.4 71.8 0 2.6 0.2 12.0 0 23.8 13.0 0 48.0 0.8 0 0.3 6.6 5.0 1.6 4.6 3.8 0 6.8 36.0 0.4 0 0 23.8 2.0 0.8 56.0 1.6 0 0.5 5.2 19.8 7.6 8.0 0.8 0 6.0 0 0.6 10.8 0.8 0.8 1.6 0 1.0 0 4.2 0.7 4.L 4.4 2.8 0 8.4 3.0 16.8 1.0 0.8 3.6 0 27.8 6.0 16.8 30.6 1.0 0 0.9 0 6.0 0 4.0 2.0 2.6 50.0 0 1.0 - -

4.0 0 0.8 5.8 0 1.6 1.1 - - - - - - -

4.0 s

I w

2 Table 10 (Cont.)

Kilometers Discharge from 1DA 2DA 3DA Origin Mar Jun Sep Dec Mar Jun Sep Dec Mar Jun Sep Dec 0.0 11.0 54.0 52.0 0 11.0 54.0 52.0 0 11.0 54.0 52.0 0 0.1 11.8 44.8 65.0 88.0 7.0 94.0 54.0 94.0 6.6 100.0 32.0 93.0 0.2 28.0 78.0 72.0 92.0 11.0 93.0 52.0 13.0 4.0 0 11.0 0 0.3 13.8 96.0 87.0 90.0 16.0 72.0 80.0 84.0 0 0 0 0 0.4 40.0 62.0 90.0 9.6 36.0 90.0 82.0 96.0 0 78.0 0 22.0 0.5 58.0 96.0 92.0 95.0 25.0 91.0 79.0 98.0 4.8 68.0 0 55.0 0.6 29.0 96.0 85.0 95.0 40.0 94.0 87.0 97.0 12.8 92.0 39.0 9.8 0.7 40.0 0 67.0 0 64.0 100.0 55.0 96.0 3.0 63.0 44.0 -

0.8 0 77.0 80.0 89.0 77.0 36.0 0 76.0 0 ,

0 -

0.9 20.0 - - -

46.0 0 -

88.0 0 - - -

1.0 - - - - - - - - - - - -

1.1 - - - - - - - - - - - -

I w

N

~-

N ~~_ -

w -

4 N _

4AN x

-x x %

iCA

? hhhh,

'7 d' h e gego A

' ggt.k@ l

, ' ' . 'f'

//

fN d O l PERCENT COVER :

Et?WA < 5 P3SMd 5- 25 G l l 126-50 o i

o,,

@M, :W:] > 5C i *" - .

l CONTROL BASIN I

Fig. 30. Distribution of Halophila engelnannii_along inside radials of the control basin for March 1979.

I-105

TAk

^ %N

~

w ICA n' .

,, hb y gig,,,,,

," O/

f C,f Wl/g '

yg.GRO O

,o '!. gt.kBU 2CA ',

!/

0' O

PERCENT COVER

[$$4?] < 5 ESM 5-25 l 126-50 o a. ,

E!F;:':2 > 5o CONTROL BASIN f

Fig. 31. Distribution of Ruppia maritima along inside radials of the control basin for March 1979.

I-106

I l

t x _ _

N %

\Ch

?*0 riwiimiwiwitweiwm y, waaaatamwammaa uw i, aawawim

, g.ys Ir7 8 '

s, YI eft-

// '

t\

\

p' ,yi/0'

\ 2Ck'!'i,,s*h,r'f'#'.

\S st U ,

Q PERCENT COVER WW4f8 < 5 VEMN5-25

[ 126-50 o o,, .

(

' i"*- [_

[ g M :i:] > 5 0 CONTROL BASIN Fig. 32. Distribution of Syringodium filiforme along inside radials of the l

control basin for March 1979.

l I-107

' N >

MAKE iCA n

.- h [jf _

V

.,gg,ff sse

'{'

/I ' tst.AtO U

O PERCENT C'OVER W Hels] < 5 M%%%f5-25 I I26-50 o p,, .

i ka-52O > 50 CONTROL BASIN l

l Fig. 33. Distribution of Halodule beaudettei along inside radials of the control basin for March 1979.

l I-108

l l

1 A

'^-- w

^

~ w w N~ %

ICA n.

i

~

n C' (/ gg,GRO f\

\l rf//{A 2C '

VY ' ****

4/

o PERCENT COVER VR Mala < 5 W/#M5-25

I . 126-50 o o,,

EE'.".81 > 50 CONTROL BASIN Fig. 34. Distribution of Thalassia testudinum along inside radials of the control basin for March 1979.

l I-109

- _ ~ "

~ -- j M TAki y _

~ w N __ , N %

~

ICA p

~

N w

O g///d- ysGR G' ,,,,ps/#'

0 ,

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sgSD fw:'

U O PERCENT COVER WMfM < 5

@kW 5-25 o o,

(

[ 126-50 i i**-

GiF',;ig > 50 CONTROL BASIN Fig. 35. Distribution of all seagrasses along inside radials of the control basin for March 1979.

i.

I-110

h

^-% __ _

N

~

l N %

lCA n.

i b ag 4:rg 45,,,,,s (f

n C',I gg.oRO O

2 CA 1: ,ipro #

1. f#

oE

\

O PERCENT COVER W M944 < 5 N'AMf 5- 25 I 126-50 o ,,,

Q

" i *"-

Eli? f. 83 > 50 l CONTROL BASIN 1

Fig. 36. Distribution of Halophila engelmannii along inside radials of the control basin for June 1979.

l l

I-111

QANIL N _

~

1CA o,

{\

\1

'/t

>M s0#

2CA ll

[

Q PERCENT COVER gr/@T? g <5 VlRiiHk5*2b g 126 50 o

\?.:y d 3 > * *

- 0%

CONTROL BASIN )

l I

l l

Fig. 37. Distribution of Ruppia maritima along inside radials of the control basin for June 1979.

l l

1-112 l

i

~

X .

^

ICA n, s

~

x% -

ff#/#/#/4

% N 7 4 f) '*"Mea

( gg,GRO 2 g, O

PERCENT COVER WfdPa < 5 F%ZMM15-25 .

[ 126-50 o o,,

i i"*-

[li33 > 50 CONTROL BASIN f Fig. 38. Distribution of 71ringodium filiforme along inside radials of the l

control basin for June 1979.

I-113

w

-x

' _ N >

~

x ICA A "*mois.

I! v.go **" aux !## spi

"""w,,,,

(f

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r\

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O PERCENT COVER E875533 < 5 PZ M 5-25 l l26-50 o,,

g o ,

' ; Ma-E:FM > 50 l CONTROL BASIN Fig. 39. Distribution of Halodule beaudettei along inside radials of the control basin for June 1979.

I-114

~

-m _

N u~x N ICA n 0

/;f hh // g pro

! 2 , y,..h. -

O PERCENT COVER E'# W FA < 5 E E 5-25

1 126-50 o ,,,

i ; x=-

Eff@>50 CONTROL BASIN Fig. 40. Distribution of all seagrasses along inside radials of the control basin for June 1979.

I-115

l W .,

-m dn V

/

I s? #' *'@ 0 Q\

,, b #

2cA '

ll,, (

0 pEBCEN1 COVER ss95;2;,

' . o.\

6 \

yff **

conTaot BAST" Fig. 41. Distribution of Ruppia maritima along inside radials of the control basin for September 1979.

1-116

~

Ax lCA x ~

~

@vagg{g r

'-lo' #Y5'

.,y;,g ;. r ;gjYA %fG"o 0 f5

2 )hfI~ *~ "#

o l O PERCENT COVER VWAR < 5

(

~

PKM615-25

[ 126-50 o n,,

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ggg ;%i:1 > 5 0 CONTROL BASIN Fig. 42. Distribution of Syringodium filiforrne along inside radials of the control basin for September 1979.

I-117 .

'-s_ N _ ___

~ ~

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g 9

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//

f\

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O PERCENT COVER

)

IWfMa < 5 PMMd 5-25

l- 126-50 o o,,

" i Ka-Bs. . '81 > 50 CONTROL BASIN 1

I Fig. 43. Distribution of Halodule_ beaudettei along inside radials of the control basin for September 1979.

l I-118

i w 'j i

-~ _

l

~

Qx l

~ N W CA

%k 2 / GON e -

(

PERCENT COVER WffA < 5 RMM'315- 25

l 126-50 o o,, .

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EiE3 > 50 J ;

CONTROL BASIN 1

Fig. 44. Distribution of all seagrasses along inside radials of the control basin for September 1979.

l I-119 t

'1 -

1CA e, l (

G)

A '###H4 I /4W

c7l qs0 1 '

i f 90 2 CA /'"

g p 'sqy O

pggCENT COVER was S*

~~CONTROL BAS Fig. 45. Distribution of Halophila engelmannii along inside radials of the control basin for December 1979.~~

~~I-120~~

l

\

~~~ -~~

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~~p,... p gi > 50 CONTROL BASIN Fig. 46. Distribution of Ruppia maritima along inside radials of the control l basin for December 1979.~~

~~l l~~

~~I-121~~

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N

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gg,GRO O p#;##-
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W Q
PERCENT COVER WMM <5 E'M$si 5- 25 ,
I 126-50 o o,,
i Ka-EC?i:i > 50 [
CONTROL BASIN Fig. 47. Distribution of Syringodium filiforme along inside radials of the control basin for December 1979.
l I-122
l i
l w
r'
~ _-
ICA n.
s
^
I 9
n c h' gg.oso O't 2CA ,,'b sst.kW
/ j' o
PERCENT COVER W97A < 5 PMM3$5-25 ,
l 1 -- 126-50 o ,,,
da-
[
i EKm:i:1>50 l CONTROL BASIN l
l Fig. 48. Distribution of Halodule beaudettei along inside radials of the control basin for December 1979.
l l
I-123
~
-~-
eh N-- _
N_
N lCA n k
' $< '{ .,
d' ,
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+ -e (
O O
PERCENT COVER EW//A < 5 W M 5-25 I 126-50 o o,,
i i"*-
E:li 'Si > 5 0 CONTROL BASIN l
Fig. 49. Distribution of all scagrasses along inside radials of the control basin for December 1979.
I-124
control basin. Its cover was lightest in March and June, becoming moderate to heavy in patches in September and December.
The four total seagrass cover maps (Figs. 35, 40, 44 and 49) show a broad distribution of seagrasses in the control basin, with the densest cover occurring in June and December. It is interesting to note that the December total .seagrass cover map (Fig. 49) is essentially identical to the December Syringodium map (Fig. 47).
The only seagrass species encountered in the discharge basin was Halodule beaudettei. Distribution and cover maps for Halodule beaudettei for each quarter in the discharge basin are presented in Figs. 50 through 53. For radials 1DA and 2DA, Halodule was widely distributed with dense cover throughout the four sampling periods. Radial 3DA showed a more scattered distriNtion with dense cover occurring in June and December only.
Two differences are noticeable with regard to seagrass distribution and cover for the inside control and discharge radials. Only one seagrass, Halodule beaudettei, was found in the discharge basin, while a total of five seagrass species, including H. beaudettei were found during one sampling period in the control basin. H. beaudettei formed a dense cover throughout most of the discharge basin, while the seagrasses in the control basin, though widely distributed, formed only a light to moderate cover.
l I-125
1 T'HUMB i ISLAND IDA l ~.
' 2u DA
.3 p
. -A ,.
~
\(i
/-
N, 3DA \ %
\
h,j,j," '., .
",,,""' -, 1 PERCENT COVER '
EYlifMi < 5 I.'65fis]5-25 0s/c i 126-50 O.I m4cE Q c4 E:si.M > 50
- x.. %(
DISCHARGE BASIN Fig. 50. Distribution of Halodule beaudettei along inside radials of the discharge basin for March 1979.
l I-126
l I I THUMB ISLAND IDA 1 l '
2DA I
. c.: ?.::. -
~~1 .::. .~~
g p
p(
s.
~~..:- r. :::.*:.~~
~~, k~~
.. r I 3DA . .. . '.'.
. . .s.
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u PERCENT COVER '.
.,:,'::;.y.,, .y.,
, W"
',,', t@, , ,
WKMd < 5 ,
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1 126-50 0 on 4E i i xm. 4+g E: E .1 > 5 0 DISCHARGE BASIN Fig. 51. Distribution of Halodule beaudettei along inside radials of the discharge basin for June 1979.
I-127
i THUMB -
l ISLAND 1
'___l D A
'. ' 2 DA l ... ::.
*S
.. .-.. . . - :..;;.i.
.i :.
.:::. :.;;,. i. : .
s.
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i. .
3 D A- !:. I,,:
ni . :. .
~~.. :. i. :.~~
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r.
i
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... : !::. }.'*:.~::,. :: :. s .
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~.
m ::- ::. I
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PERCENT COVER 'u i i 8 '!),
% ,2 '
L.,,u dM,, s < 5 v"
@' @ 5-25 %cg4 I 126-50 0.1 R
Q 4
{$;ii,3 W > 50 - i xm- C +4(
l DISCHARGE BASIN l
l Fig. 52. Distribution of Halodule beaudettei along inside radials of the discharge basin for September 1979.
1 I
i l
l l
I-128
l I THUMB ISLAND IDA 2 DA l.' x
~~.' 's~~
~~=k. -~~
. i:s'a.' ~ .
15 g:; ::.
~~. :}fii ', -~~
q 3DA - -
gj:.
'Mii'!!.:.
~
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~~%gy, 4g.'~~
^
PERCENT COVER -
EF#Rd < 5 l'?:8: M S - 2 5 49%
1 126-50 44 o os
, kii.filif.3>50
~~i x.. c4+g l~~
l l
DISCHARGE BASIN Fig. 53. Distribution of Halodule beaudettei along inside radials of the discharge basin for December 1979.
f I-129
Outside Transecy The mean percent cover of seagrasses for the control and discharge oatside transects is presented in Tables 11A through llD. The locations of these outside transects are shown in Fig. 3. Seagrass cover in the control transects was patchy and sparse with only a few dense areas present. No seagrasses were found in transects SCB and 6CB in September, or in 6CB in December.
Seagrass cover for the 17 outside disch trge transects varied greatly. The area encompassing the north-northwestern portion of the discharge transects was completely devoid of seagrasses throughout the year. This area includes l all of transects 3DB and 4DB, transects 1DB, 2DB, 3DC and 8DC with the l
exception of stations 0.0, transect 4DC stations 2.0 through 3.5, and 7DC stations 0.0 through 1.5. The remaining C series transects showed patchy, light cover with dense patches occurring on transect 1DC.
The D series of transects most clor,ely resembled the outside control transects. Cover was patchy and scattered throughout the area, with the greatest distribution occurring in June as was the case in the control transects.
Ir general the densest patches of seagrasses in the discharge transects occurred in the most shallow stations adjacent to land or oyster reefs.
I-130 l-l I
l
068 ce c 4000000 e 00000 - -
D 1 D p 6 p e e S 0000010 S 00000 - -
r B B o C C f 3 6 n 884 2 8 n 8448 s u u - -
t J 5020401 J 17220 ce s
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ce 4 c
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Table 11C. Mean percent cover of seagrasses m-2 along the outside discharge C transects for different sampling periods of 1979.
Kilometers alcog IDC 2DC 3DC Transect Mar Jun Sep Dec Mar Jun Sep Dec Mar Jun Sep Dec 0.0 40.0 45.0 32.0 14.0 8.0 0 83.0 45.0 0 31.0 0 0 0 0 0 2.0 0 2.8 0 0 0 0 0 0 0.5 1.0 8.0 0 83.0 45.0 0 0 0 0 0 0 0 0 1.5 - - - - - - - - 0 0 0 0 2.0 - - - - - - - - 0 0 0 0 Table 11C (Cont.)
s s
Kilometers 4DC SDC 6DC U along Sep Dec Mar Jun Sep Dec Transect Mar J un Sep Dec Mar Jun 0.0 40.0 45.0 32.0 0 8.0 0 83.0 45.0 40.0 45.0 32.0 14.0 0 0 0 0 0 0 0 0 0 0 0 0 0.5 1.6 0 0 0 0 10.4 0 0 0 0 1.0 0 0 0 0 0 3.8 0 0 0 0 0 0 1.5 0 0 0 0 0 0 10.0 0 0 0.8 0 0 0 2.0 0 2.5 0 0.8 0 0 1.0 0 0 0 0.8 29.0 0 0.8 0 0 0 0 0 1 0 0 0 0 3.0 0 0 0 0 0' O O O O b 0 - 0 0 3.5 '
4.0 - - - - 0 0.8 0 0 - - - -
4 9
I 1
000000 Q
@ QOOOOO (fb 8
e g C O 900C00 d u 09 OOOOOO E
4 00000O C e A
e OOOOOO 8
h g e q QQOOOO e
U M O C 4
~~i E OOOOwO w~~
U w v
.-e e o N M m0 OmOmOm e e e e e e i
M e 8mC M 4 OO&&NN J3 H 4 b 4 M V
. b . M k
I-134 s
k
Table 11D. Mean percent cover of seagrasses a-2 along the outside discharge D transects for different sampling periods of 1979.
Kilometers along 1DD 2DD 3DD Mar J un Sep Dec Mar Jun Sep Dec Mar Jun Sep Dec Transect 0.0 0 0.8 0 0 0 1.0 31.0 0 0 0.8 31.0 0 0.5 0 7.8 32.0 2.4 0 1.8 0 0 0 23.8 86.0 1.0 1.0 0 1.0 31.0 0 0 0 0 0 0 2.8 0 0 0 0.8 0 0 0 0 0 0 1.5 - - - -
2.0 - - - - 30.0 66.0 12.0 6.0 4.0 2.4 14.6 10.8
- - - - 0.8 0.8 0 0.8 0 0 0 0 2.5 3.0 - - - - 0 0 0 0 - - - -
7 Table llD (Con t.)
w vi Kilometers along 4DD SDD Transect Mar Jun Sep Dec Mar Jun Sep Dec 0.0 0 0.8 31.0 0 0 0.8 0 0 0.5 1.0 4.8 0 0.8 0 2.0 0 6.4 1.0 0 0 0 0 0 13.8 0 0 1.5 0 0 0 0 1.0 0.8 0 0.8 2.0 1.6 0 0 0 0 0 0 0 l 2.5 0 0 0 0 - - -
3.0 0 0 0 0 - - - -
3.5 0.3 '0.8 0 0 -
l l .
l l
Distribution and cover maps for Halophila engelmanii, Syringodium filiforme, Halodule beaudettei and total seagrasses for each quarter in the outside transects of the control and discharge basins are presented in Figs.
54 through 68. Halodule and Syringodium were found in the control transects during all four sampling periods. Halophila was found in June and December only. Halodule and Syringodium were most widely distributed in March and Jun e . Their percent cover was light throughout the year with a slight increase in Syringodium in December. ,
As shown in the total seagrass cover maps (Figs. 57, 61, 64 and 68),
seagrasses in the control transects were most widely distributed in June, occurring at 17 of 34 stations, and least widely distributed in September, occurring at only five stations. Seagrasses were found at 12 stations in March and at 11 stations in December. Seagrass cover was most dense in December.
In the discharge transects distribution of seagrasses was patchy.
Halophila was found in March, June and December. Halodule.and Syringodium were found during all four ss.npling periods. Halophila and Syringodium were found primarily in the D series, while Halodule was distributed throughout all discharge trans' ts. Ao seagrasses were found in any sampling periods in the northwestern portion of the discharge t , sects. Distribution of seagrasses ,
was greatest in the discharge transects during June.
Ccmparisons of outside control and discharge transects indicate a similarity in the distribution, percent cover and ccmposition of the centrol transects and '.he D series discharge transects.
I-136 i
l
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OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN Fig. 54. Distribution of Halophila engelmannii along outside transects of the control and discharge areas for March 1979. (Stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
! $ Lb ,
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. // T ,,Km l OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN l
Fig. 55. Distribution of Syringodium _f_iliforme_ along outside transects of the control and discharge areas for March 1979. (Stations monitored I
at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
~
3
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OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN l
Fig. 56. Distribution of Halodule_beaudettei_along outside transects of the control and discharge areas for March 1979. (Stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
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\\ *b a;Km l'l' 1 ,
OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN l
l Fig. 57. Distribution of all scagrasses along outside transects of the control and discharge areas for March 1979. (Stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no scagrass cover.) 9 I-140 9(W ,%-];\3 n 0 gh e Mj t'n O.,
1 I
l l
e
+
G O Q Q q'; fa ,
% . sn m . .
e "d.i '
't g 208 .f.4,.g . . ' 'd g/
g .ae # . J'. ;:
q y y e -;::
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ge 2x = .
~~.7.g..~~
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l C'. ' .:.I 2ce :- . . ;fy f,'
0 z,9 8 PER CENT COVER ses o ics 3/
4ce '+ k ses eif, @ 5-25 g y/90 O 2s-So ,
,a @ > 50 l
l} Km, OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN Fig. 58. Distribution of Halophila engelmannii along outside transects of the control and discharge areas for June 1979. (Stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
J .
s "1
." ^ l'.f . ., * .; . . .: ' %. ,,,. .:. ,a g
~~O s ,~~
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== -
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.3 g ~~5{ %~~
~~ot)TSioE gActALs: c0NT80' ^"o otsCgARGE @S i~~
Fig. 59. Distribution of Syringodium filiforme along outside transects of the control and discharEe areas for June 1979. (Stations monitoted at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
I
}
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' 8 PER CENT COVER fR,GCB ICS 7pf C
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,ys'fo @ 5-25 Q 26-50 Q ,
] s.
, # %4 A V 6 n * @ > sy yKm x l OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN l
Fig. 60. Distribution of Halodule_ beaudettei along outside transects of the control and discharge areas for June 1979. (stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
- G 00 *
. b,, ','. -
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nc
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9
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, 's: %.
'i V
s,Km il OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN Fig. 61. Distribution of all seagrasses along outside transects of the control and discharge areas for June 1979.
~
(Stations raonitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no scagrass cover.)
t t
r g @O .s,. .; . . .
~ :.'li,l
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5 6 ' 1 t OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN i
{
Fig. 62. Distribution of Syringodium filiforme along outside transects of the control and discharge areas for September 1979. (Stations
~~monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates to seagrass cover.)~~
I i
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< f. g Ce PER CENT COVER ics 7/
ses ft 11 y @ ~~5 ,0 ,,K m s~~
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OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN Fig. 63. Distribution of Halodule beaudettei along outside transects of the control .md discharge areas for September 1979. (Stations monitered at 0.5 km intervals along all 1.'icated transects. Absence of data circles at stations indicates no scagrass cover.)
~~1 A)~~
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/
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ll i OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN l
Fig. 64. Distribution of all scagrasses along outside transects of the control and discharge areas for September 1979. (Stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
1J ! ,
a,.'
.."s','1', .
406 * ~: ,1 4 * }DS .
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3 O ~~50 o~~
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Cuts \DE gA01ALS: CONTR0' 0 DISCHARGE M Fig. 65. Distribution of Halophi,la f engely.annit along outside transects of the control and discharge areas for December 1979. (S tat ions monitored at 0.5 k:n intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
\
s
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/
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O o 2s-50 g > 5{ spy 5
t1 n c OUTS 10E gADtALS OtsCHARGE @S Fig. 66. Distribution of Syringodium filiforme, along outside transects of the control and discharge areas for December 1979. (Stations monitored at 0.5 cm intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
,f 5. b
i
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OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN Fig. 67. Distribution of Halodule_ beaudettei along outside transects of the control and discharge areas for December 1979. (Stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.)
~~l ]$ L l la~~
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/!
. ,. O z OUTSIDE RADIALS: CONTROL AND DISCHARGE BASIN Fig. 68. Distribution of all scagrasses along outside transects of the control and discharge areas for December 1979. (Stations monitored at 0.5 km intervals along all indicated transects. Absence of data circles at stations indicates no seagrass cover.) l
' [ _.
Post-operational Trends: Inside Radials
In the inside discharge basin, only one species of seagrass, Halodule beaudettei, has been present since 1977. It was widely distributed throughout the basin, except along the outside (3DA) radial. It has been well distributed throughout the basin, with the lowest densities usually occurring along the radial closest to the effluent canal (3DA) . Halodule density was lowest in September 1977, when approximately two-thirds of the basin had less than five percent cover. Otherwise, cover was usually dense along radials 1DA and 2DA, and light to moderate along radial 3DA.
The inside control basin is composed of several species of seagrasses, Ruppia maritima, Halophila engelmanii, Halodule beaudettei, Syringodium filiforme and Thalassia testudinum. Three species were observed in 1977, four in 1978 and five in 1979. Seagrasses were distributed throughout the control basin for all three years and the percent cover has been light to moderate.
During 1979, Syringodium appeared to become the dominant seagrass species in the control basin. .
Post-operational Trends: Outside Transects l
Because the outside transect monitoring program was initiated in June i
1978, there are only three quarters of data available for 1978. The major trend observed, however, is that Thalassia, which was observed in all three 1978 sampling periods, was not found in any 1979 sampling period.
I-152
Oyster Reefs
~~t Oysters Two species of oysters, Crassostrea virginica and ostrea equestris, were collected in ryster reef samples during 1979. As in 1977 and in 1978, C.~~
virginica was found on all oyster reefs in both control and discharge basins while O. equestris was found only on some reefs in the control basin (Table 2).
The ratio of mean annual biomass (adjusted to a constant sample size of 230 oysters (Crassostrea virginica) to f acilitate comparison with previous i
years' data) to mean shell length was calculated for each sampling period and the results are shown in Fig. 69. The ratio in the discharge stations increased from 7.0 in March to 11.1 in June, then decreased to 8.4 in September and 6.7 in December. In contrast, the ratio for the control stations remained relatively constant, averaging 7.9. This trend of constant control ratio versus varying discharge ratio is the reverse of that found in previous years. In 1977 the ratio varied substantially in the control oyster reefs and remained relatively constant in the discharge oyster reefs and in 1978 both control and discharge ratios varied considerably, with the control stations showing .nore variability than the discharge oyster reef stations. In general, the ratio of mean biomass to shell length appears to follow an annual cycle, with maxima occurring between April and June. It was only in these months (April 77, March 78, June 78 and June 79) that the ratio has ever exceeded the value of 10; lower values were obtained in September and
~~Note: in this section post-operational trends are discussed within the separa te subseetions.~~
i I-153
OYSTERS (> 2 c m) 15-
~
o- - - -O (,0NTROL 0 0 DISCHARGE n
I o
v r -
H o
z w
>10-
_.J
_J w
I ,3 _ _ _ -o O 4 , -
N 's -
n o
v en en
< 5- ,
E O
cc O i i i i
' MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig.69. Ratio of mean biomass (adjusted to constant semple erze of 230 orstars) to mean shell length of oysters greater then 2 cm in length at control and discharge oyster reef stettene.
I-154
December. This cycle was not evident in the 1977 discharge or 1979 control oyster reef stations.
The ratio of biomass to shell length was criginally intended to monitor environmental stress, such strass being reflected in tissue atrophy. Since the data for 1977 through 1979 suggest a possible annual cycle, however, comparison of annual mean values is more appropriate for detecting long term trend s. Table 12 presents annual mean values for the biomass /shell length ratio for Crassostrea virginica. A general decrease is seen in the control station ratio, from 9.5 in 1977 to 7.9 in 1979. The ratio for discharge oyrter reef stations increased considerably between 1977 and 1978, from 5.9 to 9.3, then decreased from 9.3 to 8.3 the following year. During 1978 and 1979 there was little difference between control and discharge mean annual ratios.
In 1977 the difference was greater.
~
~~The 1979 quarterly means of adult oyster biomass m- and abundance m are presented in Figs. 70A and 70B. Control and discharge basin means were 1~~
compared using Student's t-test. The results (Table B-7, Appendix B) ind icate that oyster abundance was significantly greater in the control basin than in the discharge basin in June (0.02 < P < 0.05), Septe mber (0.02 < P < 0.05) and December (0.005 < P < 0.01) . Control oyster mean biomass was significantly greater than discharge oyster mean biomass in March (0.01 < P < 0.02), September (0.02 < P < 0.05) and December (0.02 < P < 0.05) .
Comparison of annual mean abundance and biomass for adult oysters (Tab 1-'
5 and 6) shows that both parameters have increased in both control and 1-155
l i
. l l
I t
e Table 12. Annual mean ratio of biomass /shell length for Crassostrea virginica.
1977 1978 1979 Control 9.5 8.9 7.9
! Discharge 5.9 9.3 8.3 Y
4 e
t l
l l
I-156
, - - , - - --. - . , - .- r,_ - . - - - , - - , - - . , , , , - ,- - , . ,
m r OYSTERS (> 2 c m)
O G- - - -c CONTROL
~~: ISCHARGE (n 4000-N~~
% 3000-w ce r
3 -
z 2000- ,- a s _
- s -
z e 's s ,- -f w 1000- - -
r -
~~N gy~~
~~8 0~~
' C -
n r G- - - -O CONTROL O
O O DISCHARGE CD s 400-o
l
~~
l cn 300- l
\ en !
1 x - i l r a l C 200- o- s -
- ..o i
_. s CD -
's, W ,- '
1 z 100-l x
g *
+- A 0 , , , , , , , ,
MAR 79 JUN 79 SEP 79 DEC 79 SAMPLING PERIOD Fig.70. Mean blameen per metec equered ( A) and mean ebundance pse motse equared (B) of erstees geester then 2 em et control and dischaege orstec coef stettone. Gi ve n are meane (c o n n e c t e d e t ee l e s) and stendeed devietions (rectangles).
I-157 -
~~v. ,~~
l discharge basins. Control abundance increased by 62% between 1977 and 1979, control biomass by 55%, discharge abundance by 45% and discharge biomass by 844.
Oyster Spat In 1979 as in 1978 and most of 1977, mean oyster spat abundance and biomass in the control oyster reefs exceeded those of the discharge oyster reefs in all sampling periods (Fig. 71).
Table B-7 reveals, however, that the differences between discharge and l
control spat biomass are significant in June (0.02 < P < 0.05), September (0.01 <
P < 0.02) and December (0.002 < P < 0.005) and between discharge and control spat abundance are significant for September (0.01< P < 0.02) and December (0.002 <
P < 0.005) .
No obvious annual cycle is evident in the abundance or biomass data for oyster spat. Peaks have occurred in each sampling period d'uring the three years of this study. In 1977, spat abundance was maximum in April in the discharge basin and in June in the control basin; in 1978 both basins showed maximum spat abundance in December, while in 1979 September was the period of peak abundance.
Annual mean spat biomass (Table 5) and abundance (Table 6) show dramatic increases in the control basin between 1977 and 1979. Spat biomass increased by 3624 and spat abundance increased by 434% in the control basin. In the I-158
r OYSTER SPAT O- - - -O CONTROL O = scHARoc M 4000_
s
[W3000- 'a CD <
s
/ N E ' ' -
D s z 2000- -
/
f s
o
/
/ -
0 ----
6
$1000- - -
r _
= B 9
tmy r G- - - -O CONTROL O O O DISCHARcE l
O I
s 700-o -
600-m 500-l
< A E 400- , s s
O - -
e l ' '
~
~
g 300- / N s-200-er d z -
w 100- __ ,
A E
O W Y
MkR 79 JbN 79 SEP 79 DkC 79 SAMPLING PERIOD Fig.71. Mean biomass per metee squared ( A) and mean abundance per meter squared (B) of oystor spot at control and dischsege oystor reestettons. Given are means (c o n n e c t e d eIceles) and standsed devistions (rectangles).
I-159
_..______.___-_-_____________.____m
discharge basin spat abundance (Table 6) increased by only 60% in the same period and spat biomass (Table 5) decreased.
Other Mollusks Nineteen species of mollusks, excluding C. virginica and O. equestris, were collected in oyster reef samples in 1979 (Table 2) . Of these, only four were found in the discharge basin oyster reef samples. Brachidentes spp. was the most commm taxon m discharge basin oyster reefs, while on control basin oyster reefs, Crepidula plana and Brachidontes spp. were the most frequently encountered taxa (excluding oysters) . Almost twice as many species were found overall in 1979 as in 1978. In 1977, only three mollusk species (other than oysters) were found in both control and dischargn basins.
As in 1977 and in 1978, abundance and biomass of other mollusks in the control oyster reef stations greatly exceeded those of discharge cyster reef stations (Fig. 72) . There has also been a general increase in abundance during the three year period in control stations while in the discharge stations mean abundance has remained less than 50 individuals m-2 th roughou t the period (see Final Reports,1977 and 1078).
Crustaceans It was not possible to control the escape of relatively large decapods which inhabit the oyster reefs. The quarter-meter frames canno' Se forced deep enough into the reef to form a barrier and, with the clumsy prying tools 1
1-160 )
l l
E OTHER MOLLUSKS l o 1 0 *, G- - - -O CONTROL cn j DISCHARGE ,,
N -
4h --
. , - _c )_
% 1 03, cr ----
cr W i __
-~
CD :
r .
D 1 02, Z - .o w 1 0 ',
E ! __
B 10' O- - - -O CONTROL 0 0 DISCHARGE O
W l O '-:
N O - u.
v "
/-'s .
l /
=
D l W -- ,,
/
W 1 02- <* -
cr
< i L" __
E :
O -
g --
1 0 '- --
z : __ __
~~
~
<C n ,
+ /'4 L1J r
- N y - A 10' MhR 79 JbN 79 SNP 79 CNC 79 SAMPLING PERIOD Fig.72. Me n bieness per meter squared ( A) and mean abundance per meter squared (B) for other mollusks et control and ;
discharge oyster reef stations.
1-161
I 1
l and heavy leather gloves needed to break loose the solid oyster clumps, the capture of highly mobile crabs is fortuitous at best. For this reason, the se data are not quantitative and are not treated here other than as additions to the oyster reef taxa list in Table 2.
Table 2 reveals that the same four crustacean taxa predominated in both control and discharge oyster reef samples. These are Eurypanopeus depressus, Panopeus herbstii, Xanthidae unid.. sp. and Balanus sp. The same four taxa predominated in 1977 and 1978 samples as well.
Comparison of relative occurrence data (Table 2) .for crustaceans collected in all three years shows that control oyster ree fs have remained stable with respect to number of taxa found. In 1977 twelve species were found, in 1978 eleven, and in 1979 twelve. The number of crustacean taxa found in discharge oyster reef samples has decreased steadily'during the same period. Thir teen taxa were found in 1977, eleven in 1978 and only nine in 1979.
Comparisons With Pre-operational Data: Oyster Reefs .
Comparisons among pre-operational, 1977,1978 and 1979 oyster reef da ta, including oyster and spat mean abundance and biomass, are presented graphically in Figures 73 and 74. These graphs replace Table 16 in the 1977 and 1978 final reports. Oyster abundance and biomass (Fig. 73) in the control basin were minimal in winter of the pre-operational study. Since then both have increased substantially and appear to have reached a peak in the summer sampling period of 1979. Discharge basin oyster abundance and biomass have I-162 W
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for summer (S) and winter (W) sempling periods. Data presented are fee 0.25 meter squece guadreis.
generally declined since the pre-operational study. The sharpest decline occurred between the pre-operational study and 1977, followed by a partial l
l l recovery in 1978, then a further decline in 1979.
Spat biomass and abundance in the control basin varied considerably during the period of study. Highest values were obtained in winter of the
~~pre-operational study. It is interesting to note that maximum spat abundance l~~
and biomass coincides with the period of minimal oyster abundance and biomass
~
in this basin. Lowest spat abundance and biomass values occurred in 1977 and early 1978. Winter of 1978 saw a considerable increase in biomass and abundance but since then there has been no dramatic change in either parameter. In the discharge basin, cpat abundance and biomass show a similar l
pattern; highest values recorded in the sumer pre-operational sampling period, followed by a precipitous decrease with minimal values in late 1977 and early 1978, then a slight increase in late 1978 and 1979.
l l
With the exception of the sumer pre-operational sampling period, control spat abundance and biomass are consistently greater than discharge spat abundance and biomass. The same pattern is seen in the oyster abundance and biomass data. Here, however, the single exception is the winter f
pre-operational sampling period.
1-165
Zooplan kton
%e complete list of zooplankton taxa collected in 1979, and the relative frequency of occurrence of each taxon, as indicated by the percentage of control or discharge stations at which it was found, are given in Table 3.
The means, ranges, and standard deviations for each taxon and total zooplankton are presented for control and discharge areas by day, night, and overall for each sampling period in Table B-4 of Appendix B.
A total of 62 zooplankton taxa were found during the year; 59 taxa were l
l found in the control basin, and 50 taxa were found in the discharge basin.
Thirteen taxa were unique to the control samples, while four taxa occurred only in the discharge area.
Relative occurrence data (Table 3) shows that . species occurring in both the control and discharge areas are more evenly distributed in the control basin. This pattern is also seen in the control and discha'rge eveness (e) statistics (see Fig. 78 and Table B-7, Appet.2ix B).
l Two new zooplankton stations were added for the December sampling period.
The old (outside) stations (see Fig.1) were tested against the new (inside) stations to determine whether or not they were sampling the same zooplankton populations (Table B-7, Appendix B) . Abundance and number of species were tested (Table D-73 Appendix B), with the following results. Control basin inside and outside abundance did not differ significantly (0.10 0.50) and number of species (0.20 < P< 0.50) were not significantly different. All abundance comparisons will therefore be based on pooled inside/outside data for each sampling area.
The control basin showed a significant decrease in both mean abundance (P < 0.001) and biomass (P < 0.001) between the June and December sampling periods (Fig. 75). This decrease in numbers is mirrored by decreasing diversity and evenness (see Fig. 78 and Table B-7, Appendix B) .
Mean abundance in the discharge basin did not decrease significantly between June and December (0.10 < P < 0.20), while the discharge biomass decreased nearly as much as the control biomass (P < 0.001; Fig. 75A and Fig.
75B). Diversity and evenness (see Fig. 78A and Fig. 78B) exhibited a sharper drop than that observed for the control basin.
Night versus day abundance comparisons were made for eac'h basin for the June and December sampling periods, and annual for the combined basins. Only the second quarter control means were not significantly different, with the night time means greater than the day means for all other tests (see Table E-7, Appendix B) .
Zooplankton were more abundant in the discharge basin than in the control basin in December (0.001 < P < 0.002) . Abundance in June, and biomass in June and December did not differ significantly between the two basins. The above I-167
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JUN 79 DEC 79 JUN 79 DEC 79 SAMPLING PERIOD SAMPLING PERIOD Fig.75. Mean zooptenkton abundance (A) end bloness (B) per cubic meter in the control end discherge beelne. Given are seene (c o nn e c t e d circles), etenderd deviatione (r e c t a n g l e s)
. and ranges (hor t r on t a l b er e) .
l l
abundance comparisons were partitioned into day and night components, and tested again. Once again, only the December control samples had .nean l
abundance significantly different (lower than) the discharge samples (Table B-7, Appendix B).
The general faunistic makeup of the zooplankton for the 1979 sampling periods is shown in Fig. 76 and Tables 13A, 13B and 13C. Calanoid copepods w;re the main contributor to zooplankton abundance throughout the year, accounting for between 50% and 70% of the total numbers of individuals f:
June, and between 77% and 904 in December (Fig. 76A) . Their contribution is always higher in the discharge basin than in the control basin. In June, molluscan veligers accounted for 33% of total control basin abundance, nearly I
double the 18% they contributed to the discharge samples. The veligers were of lesser importance in December, with 5.0% and 1.6% contribution to the control and discharge basins, respectively. Decapod larvae also accounted for a good portion of the total in June (10% control, 9% discharge), but they dropped to nearly zero in December. Harpacticoid copepods contributed between one and .sur percent to the total throughout the year. .
Cer tain taxa, notable not for their abundance, but for their consistent or important presence in the zooplankton are displayed in Fig. 76B, which represents the small fraction of the zooplankton, the " remainder", from Fig.
76A. Impor tance in the zooplankton is here defined as an animal that has a significant eff ect on the makeup of the zooplankton, or as a larval form that provides a source for recruitment to the nearby benthic communities. Barnacle larvae (Cirripedia nauplii and cypris) are common throughout the year, I
I-169
1 e>- CALANDID ZOOPLANKTON
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SAMPLING PERIOD Fig. 76. Percent contribution to abundance in zooptenkton i semples8 A- contribution of calenold copopods. molluscen veligers. herpecticold copepode, and decepod contribution of tems larves of to total secondary l
zooplankton abundance: B-numerie importance te the remeinder estegery er At C eentributeen o f AC ART I A TONS A. PSEUD 0DI APTOI1US CORON ATUS. and PARACAL CRASSIROSTRIS to total calenoid abundance (c e l eno i d c e t e g or y of A) .
1-170
I
(
1 Table 134. Major emplankton troups and aan numbers s*3 for day. night, surface and mid-depth tows for June 1979 outelde stations.
MID-Dr#T5/W1CET MEAN SkW A0ES A! SLWACE#3Cle? MID-DEFIS/ DAY Die Cm Die Con Die Cm Die Ce '3 is Cm Calanoid ,11994 19330 20102 14870 15222
$922 1945 14983 21705 18:49 Coppads Molluoean 4320 9453 5498 9757 3996 1470 1065 14512 4102 1506 veliters PolycAae ts 34 120 65 90 30 23 4 147 20 50 Larvae Dec epcd 3607 1747 3054 1997 1227 1140 4210 311 3213 1591 Larvae B a rn acle 500 341 203 219 416 163 137 102 562 21 0 Larvae Cyclopo:c 02 40 32 10 02 30 Copepade 92 52 124 13 rarpacticold 242 988 233 1026 239 1022 142 044 340 1249 Copepods 112 56 70 51 25 9 03 80 50 50 Chaetognathe Larvacean 0 112 12 41 4 6 4 125 0 0 Tanicates 20 22 22 16 16 0 39 14 12 20
!aopods 11 0 11 0 10 4 20 13 2 7 Fish Eggs 52 0 44 31 31 27 0 30 27 64 Ectcytocta Sch inoders 0 0 0 0 1 0 3 0 0 0 Larvae 12
0 17 7 12 0 30 13 12 14 Fish Larvae 17 3 17 6 20 0 26 S Coelen te rate s 6 14 i
Copepad 69 20 40 59 50 30 76 125 7 46 Waup111 12 3 6 0 0 14 0 0 11 Cusaceans 0 20 0 9 0 0 0 6 0 0 1 Amphipeds 0 0 3 0 0 0 0 0 0 l 3 ranch topods 14 0 3 1 2 0 0 6 0 0 Ostracods 2 20 0 0 , .2 17 x M,et.s 0 0 32 0 0 0 0 0 9 0 0 Arachnids 2 0 0 0 0 0 0 :3 0 0 Platyhelminthes 0 0 0 0 0 0 0 0 0 Fycnogonios 0 0 0 0 0 0 0 0 0 0 0 0 0 Acarles Mon s trilloid 0 0 0 0 3 0 0 0 11 0 Copepods I-171 O )O D b i 6 e A\ a d [Illi.a ,
l ile 133. Major scoplankton groups and mean numbera m*3 for day, night, surf ace and t .J-depth tows for December 1979 wtside stations.
NEAN SURFACE /WICart MID-DEP7M/ DAY MID-DrPTM/W!GET pie SimFAct/DAT Cm Die can _
Ce Dio can Die Ce A s
17982 7443 15863 Celanoid 4424 e593 12074 Copepass 3440 15468 19712 21409 772 703 490 Ito11uscan 444 515 91 720 1170 433 407 ve119ers 6 55 8 Polychaete 48 22 61 0 77 I,arvae 22 4 Decapod 0 52 0 51 - 3 40 20 68 larvae 40 la 1192 791 000 Bern.--la 1000 lose 460 253 1 09 708 993 rarvae 110 24 1 104 Cyclopoid 11 7 96 360 51 391 Copepods 116 157 Ear pactiosie 28 5 216 223 349 265 142 333 160 115 205 Copepods 25 54 42 1M 40 9 71 15 0 80 Chaetognathe 350 25 296 14rvecean 24 306 30 182 28 17 346 Tmicates 28 19 12 3 46 33 8 11 38 28 Isopode 0 0 0 0 0 0 0 2 8 9 Fish Eggs 0 2 0 8 0 0 0 9 8 8 Ec topr octs 8 2 0 Sch inoders 0 0 0 8 6 0 8 Iarvae
,1.h i.ac.se . . . . 0 . 8 .
. 0 0 l
7 l 0 0 25 1 3 0 0 0 }
Coelente rates 5 66 62 Cop' Pad 05 38 63 119 65 38 49 53 Naup111 4 13 6 4 12 0 0 8 9 2 Cusaceans 0 0 7 9 3 9 0 0 7 Amphipods S 0 0 1 0 1 0 0 0 0 0 S t ant:h topo$s 2 3 0 0 0 11 8 8 6 8 Ostracode 0 10 0 3 0 0 0 4 8 0 Nycide 0 9 0 0 9 9 8 0 0 4 Arachn16s 0 0 0 0 0 0 0
8 0 Platyhelminthes 0 0 0 0 8 0 0 0 0 8 Fycnogonias 0 0 0 0 0 0 0 8 8 9 Acaries
~~0 Mon strilloid 9 8 9 0 0 0 0 Copepals 0 A~~
1-172 'O g rpr amLq D
i l
l l
l Table 13C. Major secplankton groups and mean numbers a*3 for day, night, surface and aid-depth tows for December 1979 inside stations.
t OURFACE/DAT 00RFACE MICA 7 MD-DEPTB/DAT Mm-DrF711/MICWT MEAM Can. Die A Ole _Ce _ Dis _ h Die _ Con _ Die Calanoid Copepods $239 7501 7206 21635 4193 8972 0320 19905 8260 14003 semiluscan ,
ve11gers 106 12 D3 72 171 14 310 30 200 34 Polychsete Larvae 0 6 30 0 34 1 131 0 $2 2 Decapod Larvae 4 0 14 0 63 10 10 12 23 1 sarnsele Larvae $1 457 240 173 157 710 Set 600 244 634 Cyclopold Copepods 107 40 220 91 209 110 410 115 259 et Warpacticold Copepods ul 114 333 424 256 131 409 424 277 273 Chaetogna ms 4 0 30 TO 12 1 30 30 24 27 14rvecean Teicate s 20 10 0 184 3 37 0 255 0 119 Isopode 25 7 34 0 12 3 26 0 24 2 Fish Eg0s E O O O O 8 0 0 2 0 se toptcets 0 0 0 0 0 0 0 0 0 0 Sch inoders 14rvae 0 0 0 0 3 0 0 0 1 0 0 0 0 ,9 O C 0 Fish Larvae 0 0 0 Coele ta rates 0 0 0 0 0 18 0 4 0 5 Copepad peuplii 32 0 157 26 62 2 174 37 106 16 Cusaceans 0 0 0 17 0 0 0 85 0 20 0 3 3 0 0 0 11 1 4 Amph ipeds 0 0 0 0 0 1 Oranctiopode 0 0 0 3 0 0 22 6 0 1 Ostacods 0 0 'l 0 0 0 0 0 0 0 0 0 0 Nycids 0 0 0 0 0 0 0 0 Arachates 0 0 0 0 0 0 0 0 0 platyhelminthes 0 0 0 0 0 6 0 0 0 0 0 0 0 yy cnogenids 0 0 0 0 0 0 0 0 Acaries 0 0 0 0 Mon str111014 0 0 0 0 0 0 0 0 Co;. pods 0 0 1
1-173 9 * '
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althocqh they are more abundant in December than in June (Table 13). They were also more abundant (Table 13) and contributed more to the total abundance (Fig. 76B) in the discharge area than in the control area. Cyclopoid copepods were more commcri in December than June, while polychaete larvae, never abundant, were note common in June.
The calanoid copepods are certainly the major element of the zoop1. kton at Crystal River. Fig. 76C breaks down the. contribution to calanoid abundance This by species, clearly showing Acartia tonsa to be the dominant eclanoid.
one species accounts fo; between 33% (June control) and 79% (December Also of importance discharge) of the total zooplankton abun' dance (Fig. 75).
are Pseudodiaptomus coronatus and Paracalanus crassirostris.
Post-operationa l Trends t Zooplan kton The 1979 zooplankton samples exhibited a trend similar to that seen for 1977 and 1978 (Fig. 77), in which abundance ?nd biomass decrease from June to December. The magnitude of the change varies remarkably, however, as demonstrated by the precipitous drop in number of individu'als in the 1977 discharge samples, compared to the insignificant change seen in the 1979 discharge samples, as well as the unusually high levels seen in the control basin in June 1979.
l The above seasonal trends are accompanied by a change in the general makeup of the zooplankton, in which calanoid copepods assume a more dominant l
role during the winter months, to the point of near total dominance for the i
1-174
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1978. and 1979 I-175
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JUN 77 DEC 77 JUN 78 DEC 78 JUN 79 DEC 79 SAMPLING PERIOD Fle.79. Pereent sentributten to tetel seeplankten abundenee dwrIns 1977. 1978. and 1979 e A- contributten of mejor tema grewpe to tetel zeeplankten abundances 8 centetbutten of ACARTIA TONSA to tetel neoplankten abundance.
i December 1977 and December 1979 samples (Fig. 79) . This increasing role of calanoids is mirrored by a decreasing number of larval forms.
December of 1978 was the only sampling period that did not fit into an otherwise clear seasonal pattern. The calanoid copepods did not dominate the waters as such as they did in December of 1977 and 1979, and the molluscan i
veligers actually increased their relative contribution in the control basin between June and December 1978. The seasonal distribution of Acartia tonsa essential *.y mirrors the distribution of the general calanoid category. This copepod accounts for more than 60% of the total zooplankton in December 1977
~
and 1979, with a low of 20% for control samples in June 1978.
i It is interesting to note that, while the abundance and biomass in the discharge basin are generally higher than in the control basin, the opposite is true for diversity and evenness (Fig. 78). This trend indicates that the larger number of animals found in the discharge basin are made up of a smaller number of species, among which a greater degree of dominance than that seen in the control basin prevails. This pattern is shown in Fig.*79.
Diversity and evenness values reflect the f aunistic trends seen in Fig.
~~79. They are at their highest point when the calanoid copepods show their 1cwest levels of dominance (June 1977, June and December 1978, June 1979) .~~
I-178
DISCUSSION AND CDNCLUSIONS Differences between the control and discharge areas which existed prior to the operation of Unit 3 have been discussed in the 1977 Final Report. These physical differencas continue to have major effects upon comparisons of at least the benthic communities of the two basins. For this reason, the basic factors associated with the variable characteristics of the two basins are repeated below as an introduction to the discussion of the 1979 results.
Significant divergences in physical conditions and in the structure of biological communities probably commenced with the early jetty construction 1
and resulting alteration of current and sedimentation patterns. These processes have acted in concert with long term effects of the total plant operation over the past 13 years to provide the present unique environments observed in the separate basins. Since temperature, salinity, current patterns and bottom types are different between the two basins, the benthic community differences attributable to plant operations alone are difficult to j identify, Measured community structural parameters show much variation over time. Ef fects which may be due to changes in plant operations, therefore, l
l l cannot be detected by simple comparisons between control and discharge areas.
At this point, it seems that in order to look at the effects attibutable to plant operations, it may be necessary to attempt to factor out information relating to normal community structure variations, variations due to potential annual or seasonal cyclic changes, and differences between basins attributable to physical differences between basin structure, substrate, current patterns, etc. Key to this analysis may well be an investigation of community structure variation on a station by station basis over time.
1-179
l
}
An additional obstacle to impact analysis of the effects of Unit 3 operation was identified in the differences in technique which complicate the evaluation of dif ferences between the pre-operational and the 1977 study.
Additionally, the potential effects of Unit 3 operation may not have yet been realized due to the fact that the plant has not operated continuously over any given year. Unit 3 did not go into operation until March 1977, was out of i
l operation between March and the end of September in 1978, and between March and August of 1979. It is perhaps significant that, over the last two years, the plant has been out of service during the warmest months, the time when plant effects could be maximal.
During the prolonged plant shutdown in 1978, the mean temperature dropped 1.3 C and the mean salinity dropped 0.8 /oo from the corresponding 1977 means for the discharge basin (Table 17B, 1978 Final Report). However, for changing physical parameters such as temperature and salinity, it is unlikely that measurements taken over only four weeks of a year would generate valid annual means. Further community analysis should be undertaken for the past three years' data combining information from other technical specifications reports for these periods.
We have presented some information on possible trends detected in post-operational studies, and comparisons between post- and pre-operational periods. Hopefully, by the end of 1980, a more definitive set of trends will be enumerated, if such trends, in fact, exist.
1-180
l RITERDICES Cushing, C.E., Sr. 1961. Limnol. Oceanogr. 6: 489-490. ,
1 Dawson, C.E., 1955. A Study of the Oyster Biology and Hydrography at l Crystal River, Florida. Inst. Mar. Sci. 4 (1) : 279.
Florida Power Corporation,1974. Crystal River Power Plent:
Environmental Considerations, 4 Volumes.
t Florida Power Corporation,1978. Post Operational Ecological l Monitoring Program: Crystal River Units 1,2, and 3. Annual Report 1977, 2 l Volumes. .
Florida Power Corporation, 1979. Post Operational Ecological Monitoring Program: Crystal River Units 1,2, and 3. Annual Report 1978, 2 Volumes. _
Grimes, C.B, 1971. Thermal addition studies of the Crystal River steam electric station. Fla. Dept. Nat. Res. Mar. Res. Lab; Prof. Paper Ser.
Ils 1- 53.
Grimes, C.B. and J. A. Mountain,1971. Effects of thermal effluent upon marine fishes near Crystal River steam electric station. Fla. Dept. Nat.
Res. Mar. Res. Lab; Prof. Paper Ser:. 17 1-64.
Lyons, W.G. , et al. , 1971. Preliminary Inventory of Marine Invertebrates Collected Near the Electrical Generating Plant, Crystal River, Florida, in 1969. Fla. Dept. Nat. Res. Mar. Res. Lab; Prof. Paper Ser. 14: 1-45.
Ma son , W.T . , Jr . and P .P . Yev ich . 1967. The use of phloxime B cnd rose bengal stains to facilitate sorting benthic samples. Trans. Amer.
Microse. Soc. 86: 221-223.
Moun ta in , J . A. , 1972. Further Thermal Addition Studies at Crystal River, Florida with an Annotated Checklist of Marine Fishes Collected 1969-1971. Fla. Dept. Nat. Res. Mar. Res. Lab; Prof. Paper Ser. 20:
1-103.
Phillips, R.C., 1961. The Ecology of Marine Plants of Crystal Bay, Florida. Quart. Jour. Fla. Acad. Sci. 23 (4) .
Steidinger, K.A. and J. F. Van Breedveld,1971. Ben thic Marine Algae from Waters Adjacent to the Crystal River Electric Power l
l Plant. Fla. Dept. Nat. Res. Mar. Res. Lab; Prof. Paper Ser.16: 1-46.
! Van Tine, F. 1974. Report D: Comparisons of the benthic flora in estuaries adjacent to the Crystal River Fower Plant:
Environmen tal Considerations. Final Report to the Interagency Research Advisory Committee. Vol II.
I-181
A -
t l
APPENDICES I
l t
t V
4
Appendix A Common and Scientific Names of Economically Important Species From 1977-1979 Collections Common Name Scientific Name Virginia Oyster Crassostres virginica Borse Oyster Ostrea equestris Bay Scallop M opecten _irradians Blue Crab Callinectes sapidus Pink Shrimp Penaeus sp.
Acorn Barnacle Balanus sp.
I-A-1
m . a.
) . .. ,
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Table B-1 (Cont.)
Comer.LL mETCALF & EDof left 44stm . Etsmin0L NEP087 FnA SECDen cuapTER ROTT0m Cued: FLONIDA Pours ComPOR473ng evtgaLL C044098TV STauCTume. Stung af CatstaL pivEn P0eER PLAST
~~=====sumptp 0F INDITIOukL8========~~
~~====PER SQueAC NETER****** **** WET WEIGNT**** **=* DST WEIGHT ****=~~
TA10m N NEaC RANGE STO DFV TOTAL arassm2 1n146 stampn3 PN T LHN POSIFEs4 42.900 0.903 13.4870 3.5336 unto. 6P. St. 88.3 8.= St. 23.75 PMTLum COELEntEwaft 8.390 e.310 0.3S97 0.0589 CLa58 amTNut04 -
unto, sP. 35 S.8 0.= 35 St.39 CLASS SCTPuntos umIO. mEDUSAC 3S. S.I S.= 25 II.39 PMTLue PLATTMELmINTNES 9.076 8.985 0.0051 0.0019 uusn. SP. 337 35.5 8.= 427 56.94 8
Pnthug ASCHELMINTMES L.103 0.030 0.0351 0.0018
~~= u.io. ... .l 2. i322.3 . 2.. .033 .6. . .~~
~~P.TLu. .Em<.7,.Ea unto. SP. S09. 105.9 16.= SSI. 38.19~~
..i2. . 33. .. . 3 .. 3..
PNTLUE StrueCUL4 8.538 8.306 9.3443 8.0413 uulo. SP. 102. 29.4 S.. 16 33.30 PWILUM CHAFTOGm4 Tut 8 0.0 0.= 0 4.00 unto. SP. 35. S.8 S.= 35 St.39 P4T Lese ammELID4 107.344 31.469 63.3900 13.4190 CLASS OLIGOCNaCT4 u=IO. SP. 440S. 048.8 255.= l4St. 411.02
, CLASS POLTCWa*:74 t FAutLv avantLLI0ag .
asamtLLa lugCOL0s 321, 25.5 e= St. 25.46 FAutLT CaPf?Lt.LinaE CaPIT*LLa CAPIT&T4 3430 607.S 329.= leSt. 669.85 stutomastuS CALIF 04elENSIS alle. 422.7 127.* 085. 263.10 uofnmasfus SP. 25 S.I 0.= 25 88.39 untD. Sr. 153 30.6 0.= SI. 28.38 FAelLV ClewafuLinst twauva sr. 3730 14s.6 407.= lete. 267.93 rag:Lv enusCina'
~~i '~~
~~LvSlusCe us=FTT4~~
~~amparsa sage.usmCa 25 357 S.s 18.3 0.~~
c..
25 tit.
18.39 81.10 D 9 }". , 0 s
hf) i i
ras Lv rL a ne ts. s ci u s pa r. '
. %O' ela ed) ,j U rawne s s e.nuCa 802, 30.4 0.= 74 33.20 FeetLt Ct.TCt a g na6 GI.TCrus a.e.afCa44 35. S.8 0.= 35 88.39 FaulLf GO4 l a h l b a t.
LLtCenut sp. 102. 20.4 0.= St. 31.90 F a u l t.f wt 5 8 8t= 3 n4 6
~~8;v PT I b udsvlPal.P4 255 50.9 St. St. e.0u ug I 88 SP. 26 S.8 0.= 25 St.19~~
l l
l 3 Table B-1 (Cont.) CometLL stTCal.F & Enov 5979 i
masim = rouTWnl. nFPost Fn# SECDm0 SUAeffe l FLueID4 Pneta CnaPoaATION OTgnsLL t entfog Coat CnemumITy SteuCTunt stung af CarstaL RIVEa Ponen PLAqT ..
====muesta OF In01WIOUALS**=*
....... Pts senaaC mETEa====.= ..**uCT utICNT==== ====Det #EIGNT=**== -
N miam namGE STD DEV TOTab PEAN /m2 TOTAL DEAN /m3 Taxou ,
FAMILY LummelutaEI0aK LuotmI4 tuts **. 802. 20.4 0.= St. 21.38 ,
FAMILY uarr.o.InaF 4&GE8 An Prfilwo4Eng 127. 25.5 d.= 76 36.08 FA4ELT maLDanIDat
%4InfuFLLA 40C054 866. $13.2 0.= 433 195.93 muamCulo4STCHIS AeERICANA lit. 35.7 0.* 127. 55.79 CLTurutLLa Tnm004T4 102. 2u.4 0.= 102 45.5%
stain. SP. 102. 20.4 0.= 76 33.20 FaulLY wr.aEinaE 4EnEIS FALSA St. 10.2 0.* St. 22.70 NCREIS SuCCinfA 74 15.3 0.* St. 22.70 PLaTV4FmEl3 DumCRILII 25 S.l 0.= 25 88.39 pq UNID. SP. 157. 78.3 0.= 327 58.07 g
F4 ally oeuPulpaC OmupnIS arnoLnSA 1630 325.9 55.= 509 178.20 ca 8 FAMILV OM4543RDaC
p. MaPLO5CDLOPLOS WORUSTUS 631 127.3 25.= 338 126.04 c- malgtmEIS SP. 4ne. 96.0 0.= 407 376.79 5 Col.0PLns a9 man 4st. 96.0 25.= 1S3 55.21 F44tLT OwLnIInaE Owfula FusfroemIS 127 2S.S 0.* 16 36.08 FAMILY Passomlost amICIDEs PHIL884&E 4049 009.0 25S.* 3609 S35.49 ARICIDEA TaTLOnt 3370 275.0 25.= 1146, 401.63
'lC aulCthea SP. 229 43.0 0.. 127 48.90 h Pasanglut$ SP. 1995 Juf.8 16.= 8897 47%.u6 h St. 40.2 0.= 2$. 13.9S U410. SP. FamILv P4TLLunnCinaE Efe0*t METEROPnna 229 45.0 0.* 16 33.20 h5d[bh FMTLLODOCL aWEmaC St. 10.2 0.= St. 22.70 Helo. $P.
~~76 IS.) 0.= 25 33.9%~~
~~FAmILt Pne.CILocnnefloat PUF.CILOCMalfu% JnMasnel 107. . 20.4 0.* 102 4S.SS (L__J) FantLT %anELLIpat 27... 30.. .S.9.~~
~~;3cgg C n.t ...r.,~~
~~FanulCla 59 ii?.. 3R78 '34.I 7... 802.= 54St. 520.0S ramILV Sa>6LLapII0aC h f) t--- , SapELLaula vuLGauls FaulLV Scattnpec=Ioar~~
~~$27, 25.5 0.= 102. 44.58 +~~
tr MfkosrnLFu e.nuGistfa St. 10.2 0.= St. 22.70 (7-t FaulLT StwpoLloat unlu %P. 4235 850.5 0.= 2052 1246.03 y @~ F a u l e. f Sr s na l n a 6: 40.7 0= 66.40 r --- , Pawarutn%nsvin PImeATa 204, ISn. Potynn%s .6nhT6ul 2989 $9%.9 25.= 2410 404g,48 U 76 38.20 Puln44%Pld writ etsanagCHI A In2. 20.4 0.. sent80*Pl5 Anussage in2. 2v.4 0,= 16, 33.20 . STwrphemPin utsenICTS 25 S.8 0.= 25 30.39 U440 Sr. 16. 85.3 0.. St. 22 70
Table B-1 (Cont.) CommELL mETCatt E EDD7 1979 maste - C04Tp0L aFP0af ron SECome Guaaft8 a07T04 Coat FLoutua Poeta CnaPOmaTassa ottanLL CuanugITT sfauCTUNE STHDT AT CaTSTab NIVEN Posta plast .-
^ ........hugsga er Imp 5TIDasALs...====. ===...=rEn 500 ant mETEa====== **** WET WEIGNT=*== **** DST wtIGNT===== .
~~Taa04 N Peau kamCE STD DEV 70786 mEasin2 TOTAL stauss2 r&RILT STLLIDaE~~
saansa CLavaTA 200 56.0 0.= 200 825.27 Eancner DISPau 1820. 224.1 127.* 404 147.03 ODomin5TLLIS SP. 25 i.8 0.* 25 II.39 STLLIS SP. Elle. 662.8 St.. 1106 763.38 Uelp. SP. 327 25.S 0.= St. 25.46 ramILT TEREntLLloat FunPinMaa4CMUS S.WCHINEUS St. 80.2 0.= 25 13.95 LTSILLA ALMA S278. 1954.2 229.* 2292 8029.45 PISTA CAI5faTA 204, 40.7 0.= 121 50.62 PI$7a $P. 25. S.8 0.= 25 11.39 StatntosOsa MantmamAC 2%. 5.1 0.. 25 39.39 fteEnELLIOES Sfa0E4tt 25 S.3 0.= 24 II.39
~~>< unto. $P. 25 S.I 0.= 25. 18.39 1~~
tp PNTLue nOLLUSC. 8 CLASS A=PHincusa 0.942 0.800 0.5555 0.8150
>d FamILT aCA*TMOCNITominat Ln acamTW4CMITnen PTGearA 327 25.S 0.= 102. 44.88 ,
raagLT ISCggnCMITu=I0aE 85CHWHCMjTn4 PaPILLO508 255 90.9 0.= 127 59.72 Class savaLvla 154.012 33.362 184.0944 22.9782 Lat.VICasolum conTONI 16 15.3 0.* 76 34.16 FaufLT CapotTInaC CapDITaaraa FLonI0ama Set, 808.9 0.= 302 160.04 r488LT q.asaEgnat aLICtea itaastata 127 25.S 0.. 327 56.94 rantLT Lb.PT44 t D a s. eTSEl.La PLamus.Afa 76, 15.3 0.= 76 34.16 ramtLT LTomstinar Linutta MTat.INa 76 15.3 0.= St. 22.10 realLT mattagnat maCTwa ranc Lis 25. S.8 0.* 25 88.39 FAMILT uTTILinaE esatugnngfr4 DnatuGENSIS 302. 20.4 0.* St. 27.90 musCutus LaTEaALIS 127 25.S 0.. 76 36.08 ransLT aucnt.i n a t.
~~=utoba C . m.ata 16 IS.3 0.- 16 34.36 '~~
r;3 . . r a. i i.T ,,st. t n a ,- D D l t CuassnsTwoa vtaCINICA 25 S.8 0.= 25 33.39 fr "I k nstata Lnuestnis 25 S.t 0.- 25 11.39 lib stjdj U U u;nb r a ml e.T P&.w e Ps.9= a f i n a r. - woulPLnen sp. 735 847.7 0.* 407 167.37 ram 1LT se=sLtpat Cedler.la %p. 25. S.I 0.= 2S, 18.19 - t as s t.T T* Ls.l e s n a r f*LLima fosana 25 S.8 0.= 2S. 81.39 T D t.I.l g a sp . 2'29, 45.a 0= 16, 13 28 - F a s tl.1 9 6.m6 M i n&E
, fra"%D.96.t l.a C04Ranf Na 76 $$.3 58, 27.10 =
~~wee w.. m.w e . e e s se- w~~
~~- --,-w - , - -- - - - - . _ , _ _~~
t I l i i r Table B-1 (Cont .) Com1tLL stTCair 4 F003 1919 nasi. - Cnntant mern T ene arCn=0 ouestes FLumIpa Posto Co#Posaflow ovFpaLL anTTom Cout:
~~Cnmuualft struCTunt. Stung af rul5f at mITf:n roula PLauf~~
==...... mum st a sie ihn t v l 0u abs........ .=..==. Pin 50'samt mFTLA====== *==. MET urtCMT==== =*==Se1 wtIGNT.==**
Tatum ,'n spam namCE STO DET Total Prampu2 TOTab Rest /m2 , ChaSA GaStunroca 21.049 4.310 84.5042 2.9112 F a u ll.T aCTpurimlung aCTFitClea CamaLICULata 280 56.0 0.= 327 40.10 FaulLT Catrinat C a 8'CH 4 Pue,CHELLum 121, 25.S 0.= St. 21.46 Captue SP. St. 30.2 n.= 25 83.95 FamILT CetPinqLinst CWF Plu"La marest.rsa ten. 137.S 6.= 382. 144.12 Corplenta pLama 181 142.6 0.. 347 395.27 CmFPSPHLa SP. Ste. 182.0 0.= 4%#, 195.21 r a m i s, T CsnllHilnaE C991Tdlum mH5Capua 25 S.l 0.= 25. 89.39 pg elfine vaelue 127 2$.S 0.= 142, 44.11 I Faull.T Cnth e>6 Lt.ina C CO alfwtLLa s.nmaTa toe. 137.S 59.= 338 126.ul i Faull.T samGlasLLinap
>= GemmesLima ovubtronMIS 102. 20.4 0.= 16, 33.20 Ch mamLlut.Lt.a apICIma 182 20.4 0.. 25 18.19 ma4Gim* l.La nues;4CimCTa 25 Set 8.= 25 II.39 v OLivel.LIDaE FapIL,LivrLLa mutlCa e 25 S.l 9.= 25 Bl.39 famILT PThaeIntLL10aE noosinala $P. 294 so.? 0= 16, 34.86 TuonowlLLa sp. 25 S.l 0.. 25. 88.39 r a m II.T vlielatLLinat T F I m's.*>1 H e a SP. 102, 20.4 0.= 25 89.39 ~1h3)
FaulL1 Vnt.v 4 TFLLI G A C CfLIm080HHLLa ktault 107 20.4 0.= 102. 45.S5 PMTLue amTunnenna L. class CwnstarFa . 74.184 84 **3 15.3268 3.0252 SupCLagg Cnetrona siw 0F.4 Cat.amo g na Hel0. Apr. TI). 142.6 0.= 596 249.#9 (Cr. ) pent e CTCLop"It'a u=IO SPp. 25 S.I 0.. 25. St.19 Oens e wasPaCTIC0tha
, unen. SpP. St. 30.2 0.= St. 27.1R SHmCI,a ss HSTwarnua naln, sus . 981, le3.3 St.= Sls. 199.29 L'_"]
i L ,j c'a'-, SumCLaSs was.aCOsteaCa Ownte CguaCFa 9419 sp. 327 25.5 0.= 74. 36.08 t: F a e ll.T DiaNfVLSDar u=In. svP. 74, ts.) 0.. St. 22.18 = c -~i [ oens e Tamaluatea LJ $sgennu G6 m b I e it eyps,0w a
'9454 SP. la. 15.3 0= 74 34.16 Sumow r4 u ungoo n=npemm a 'lu t h. SP. 3044, 200.9 0.. 713, 299.45 ,
i Table B-1 (Cont.) Clematt-L *tTral.F & EDUT 1919 pasim - Cngtone, wEpcot Fna SECneD OuesTEe FLOmIUa Postu ComPopaTID4 OVEpaLL
~~#DTTDs CurF .~~
~~ComunnlTV STRUCTupt Stung af fag 5 Tab PITEp resFe plant~~
========muents or ImpivlDuaL5*****=== = == ====Pe n staH a s t s9 7t h == = === ====mFT WFICMT==== ====Def WEIGHT ===*=
x 4LaN #s4bF STD uEV Ynfah Pfau/m2 fnfal atenss2 Tal44 D#nt N ISOPopa U m l et. SP. 25 S.1 0.= 21 II.39 Fam!LT amThou!Dat gelo. Sp. 76 15.) 0.= St. 22.10 Fa88Lf FaCnpaLt.aglDag Held. SP. 29 5.1 0= 25 88.39 FagILT INHIEIDaE 4480 Sr. 535 101.e 0.= IST. 144.50 FaulLY SPHagequafggag q=10. Sr. 2052. 402.3 25.= 1846. 476.20 DoDEs ampulpoon umIO. 5P. 321 25.5 0.= 102 44.88 en FamILv amptLisclDat t unID. SPP. Ell. 66.2 9.= ISS. 66.40 00 FaetLt a*PulLOCNIDat 863.05 I n=10 SPP. 637 127.3 0.= 304
** FamlLt a4PITM0lDaF 4876 1084.57 *J G41D. $PP. 9718 1955.7 102.=
FaetLV acelnaE 540.88 Halo. SPP. Self. 1903.3 229.= $655 FaulLT 9af>IDaE UW10. $PP. 333. 66.2 9.= 204, 70.72 . F a u ll.1 CapatLLlDaE Held. SPP. 917 103.3 25.= 458 $90.05 FastLT CotomaaflGIDat 23 04tD. SPP. 25 S.8 0.= II.39 FaulLv CnenwullDsE 4480 SPP. 115 3%.? 9.= 153, 44.40 FamILT LF.4 COT M0! D a t 157 140.92 9mtD. $P. S15 107.0 0.= FAMILT LIL.lfRORGilDat . le6.68 HalD. $P. 066 II).2 0.= 4it. Fau!LT Lt%Isma%51DaE 13.95 esgID. 4P. St. le.2 0.= 25. Faufby sFLITIUaF o in. sP. 9. i.3.3 0.= .01 i.,.4 I cg j
, apri, } , pf f
h > FaulLY owLla=TIDAE o, D. sp. >S. S. 0.= 25 . 39 en 4 l,jna[h ,; gj}jng;[a !;, Fan tl g Pwas oCFPu a LI Da t; segin. SP. Sim. IS.? 4.= 76 29.#8 FaulLY Ps t4 f 0CF e E l D a t. 44th. $P. St. 10.2 a.= St. 27.7a nante O. C a pein a Feeltf fsLs.lan455tuat u=lu. Sp. 802. 20.4 0.= St. 2 8. II FaulLT MlwPnLTTipsF glyrenLvit Ps.s esp atagf u a 127. 2$.5 8.= 102, 44.18 e se t s,y p at.Hwl n a t pecqwus %&P. St. 30.2 25 83.95 en=les, sp. 2S. S.8 2%. fl.19
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& 5 to O O m OM M P OF S e e TSom e i 909 m a > e e Sk e M m e MMMm e e 2 0 $W m m a e m m W G E m D 0 W Em @> e e e e e o e e > QE Js e e e e e e e e e e e e e e s e e e C +-= et O O e Om M e Oc e e e Mmme d O e=# e # e > c
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&&w m: 2 9 bO2S C@e # $ 6 8 8 0 0 8 8 0 0 0 9 5 S S S 5 0 9 0 0 S 8 0 e e o e o e e e o e o e e e o e e o e e o e e e Ja*b 3WE e o @ 000 O O O O C 4 U m O O O DO O O OO e O O eDOO O M
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~~J. J. ,a qu> oppeay e= W "2 *W4f34 "3 IJ~~
~~=r3 a **JJ 4 .~~
E & =S& A& W& S& W J&h Z g 3 =6eM&*ga 1Fu e*10 6 J h o r. JW =M EW JM F e d eMJ3 ee O&J3 ede g a F # f M m e #. 4 1 02Je
%# TZ===>C Je4#1=eCe2 'a NC w a =
~~e e~~
=
U e Up Cp Oz my ogg a y t g ey>g Ca 3.a =k e a ; equy>4r> ogA ZmJ3 3 a3 =* 4 EN e 2 e J e U K 3 WCS >C EO E0 WO >= JCCu m mWmO O a &e=
~~'J =~~
W= == Z &P2= e 3 3= 3 a M U Ja= >= Ze k O hC=> J =
>ek e W e* War er UF E F &F d e F-2J>wwb>e44r>&mT>ea wasCJrJwJuza=JyJkJer=JcJeJJanJe F>J>mm g == Cm= J= wm Wm me W ze m e = = = = =
~~N CC UE & 4 3 U 40 &= a~~
~~= =~~
~~y a 3 5 5 8 [~~
. .U. . . . .a .E .E .E .S . e. . e. -
e M => C Je J J J J J Je l a ek e D J > > > > > ma J i eo e ru r x z r z zu v b OS > & & & & & & & im I-B-20 D k e
Tabic B-1 (Cont.)
=
CONNELL 4ffraLF 6 F003 8979 esSin = nisCuawCE strnNT Fnt anTTug COAL SEC0m0 SUAaTER FLualDA Pnw6.m CnaPoaATION OVERALL
, Conguelff StauCTUht. STuoy af Catsfah WIsla Poeta PLA47 . =======*muu>ER OF I40lvipuaLS======== =======PFu SOHaut 46.TE4====== ====ulf WEICMT***= ****Def WCICnT=====
TAIOM N #EAN #ANGE STD DEV TOTAL Peau /m2 TOTAL NEAN#n2 ORA 4CM10aSVCNIS A*ESICANA 76 10.9 0.= 25 13.68 Family gFaEinat
~~Larnatet.IS CULfLug sea. 120.0 0.= 407 343.33 48.HEl$ SUCCimCa St. 1.3 0.= St. 19.2%~~
unID. Sr. 25. 3.6 0.= 25 v.62 FantLV 040 PM 10 a f: ul0PaTa4 CHPMEA 102. 14.6 0.* 25 83.68 natsPHIS ge noLelan 68.8 FAMILY nuglellD4E 433, 0.= 382. 343.67 MaptoscnturLn$ ROGUSTUS 407 50.2 0.= 870 15.99 SCOLnpLns pussa St. 1.3 0.. 25 12.43
~FAalLT O*L4flDaE uutulA Fu$lreautS Inl9 145.5 0.= all. 226.60 ,4 FAAILV Pana04fDat g ANICIDF a FN Af;18.j S St. 1.3 0.= St. 19.2b Os apICIDEa Pn3Luluat 24848 3443.7 1980.= 5067 3328.01
Am Clota TAvtool 80364 14to.6 637.= 3598, 999.25 og anIClota SP. 1%%3 228.9 St.* 382. 337.69

p. PaMaO* IDES SP. 2#0 40.0 0.* I S S. S2.72 U4fD. Sr. 25, 3.6 0.= 25. 9.62 FaaILV PNTLLOOOCI0at PuvLLupnCE antwAL 76 10.9 0.= 76 20.a7 PHTLLonuCE SP. 25 3.6 0.= 25 9.62 UNIO. SP. 25 3.6 0.= 25 9.62 FAmlLf SARELI.lBat CuomE pume.s t 2037 298.0 25.= 783 255.43 Fam8ICIA SP. 2285. 386.5 25.* 8579 570.18 FAMILT St#PULI0aE uMID. SP. 25. 3.6 0.= 25 9.62 FAMILt SPIOgIDet PanAPNIOmnSPIO PINNATA 942. 834.6 58.= 407 332.u9 Pne.vnnan sP. 2s; s.6 0.= 25 9.62 PHLT09ka stmSTFAI le2. S4.6 0.= 878 61.3u PMIO4u%Plu HFTra084AuCMI6 560 00.0 0.= 151 53.as SCOLELtPIS SQua4AT4 993 141.9 0.= 609 294.16
~~.] $ )~~
STwe.4LnSpin MFgLDICT! 5704, 414.9 St.= 1604 598.65 i U4fD. SP. 76 10.9 0.= 2%. 53.6% > FAnlLT SVLLIDAR ' { l taucn=E n: SPAN lie. 2s.s n.- iO2. is.90 jh- l g d,t A'ul;a SYLLIS Sr. 509 12.0 n.= 153 68.34 HalG. SP. 76 30.9 0.* SI. 20.04 FaulLY TEuFhtLLI0aE LySILLa as,ma 25, 3.6 0.= 25 9.42 PHILum m0LLUSCa CLaSt MlvaLyra pae Lv Irue$llhar 44.2%g 6.325 25.27ea 3.6833 Lyngsta usatlwa 16. 30.9 0.= 16 28.87 FAuthy mucutautuar NHCHL&4a .NP. 1.3
~~, St. 0.= St. 19.25~~
Table B-1 (Cont .) CummLLL ap'TCal F 6 6:007 9979 nasta = n t 3Cnaer.t pF Pnut s po 8FC040 OUARTEp anTTne CnsF fLowlpa P0uth CotP0maflow OVEpaLL coneualTT ST>uCTukt STUOT af fpfMTab hivER PosLP PLANT .
========mushte nF ImplvlpuaL5======== =.=====pp m SQua n E m6 T6 a ====== ====uET WFIG47=*== ****0WT WEIGNT===== .
T4304 W #844 MaNGF Sin DEW 70 Tab 86 autM2 TOTak mEAN#u2 FantLT PeelPLnenfloag PeplPL8saa SP. 327 10.2 0.= St. 39.25 FaulLV T *'LL i m i n t F maComa CngsfulCT4 25. 3.6 4.= 25 9.62 ftl.i.lma Trnaga St. 7.3 0.= 2S. 82.43 TEl. Lima AP. 102. 14.6 0.= 16, 25.W1 Cl. ass GasTe9poua 13.900 9.997 10.0098 1 4483 Cl. ass castmoPnna 0.827 0.01g 0.096e e.nl30 Fa4ILt aCTtoCleluat aCTEnClea CanaLICULafa II46, 143.1 St.= 40s, 369.30 Fa4ILY CAEC10al CaEcus PubCHELLUm 302. 54.4 0.= 153 59.59 P4 CatCue SP. 2S. . 1.6 0.= 25 9.62 8 FaulLT CaFP90ULIDaE U" Cappinuta Pl.ama 25 3.6 0.= 25 9.62 8 CpFPipul.a MP. St. I.) 0.= 25. 12.43 h#
# Da88LT CDRIT4flDat niflue vaelun 1299, les.S 25.= 404, 173.1e FaulLT CnbunnFLLinag affaFLLa s.neafa S60 00.0 0.= 17s. 64.50 FaulLT 4 4 55 a e l n a t.
MaA5aelog gles t St. 1.3 0.= St. 19.25 FadlLi P f k a m l D f. LI.8 0 a C omostnata SP. 164 109.1 0.= 333. 133.68 TesehnwlLLa SP. 25. 3.6 0.= 25 9.62
/"*~~ Towa04 ILLA INTfAUPTa 25 3.6 0.= 25, 9.62 YTJi[}- FA48LT wB5sninaE 25 3.6 25 9.62
{-, alcmouoCHus SP. FangLy Telmalnat 0.= CSI(hh PVRGOCf7 News PLICnsa 25, 5.6 0.= 25 9.42 Fanti.y v I Te l e t Lt.j pa r. TEttH570*a SP. 7 6'. 10.9 0.= St. 20.04 OoDEN wupintanCMla br--___ uglas sp. 76. 30.9 0.= St. 7t,94 PMTLua 4WTha pnn a o La -J Cl.a s S Censf acy.a 9.855 1.400 2.5899 0.3594 Suncl.4 55 COPFPuca
,e OW0ss catagnina c----' u iu. s, . 4a4. 6..i 0.= iS3, S2 LCE~TS3 nonte CTCLDPolna -- -' uwln sPP. 102. 14.6 0.= 102. 3a.50 E7??; fpNnFW MauPACTICnina " ~
usin. SPF. 454 65.5 0.. 407 lSt.J7 SupCha%5 nsTearuna .
}T~~~' "41u. SPW. 2954 422.0 0.= 1989 376.23 Suprf. ass m a s.a roS Tw a r a nwiss Co are a ugin sp. 113. 101.9 4.= 433. 158.37 . F a = 11. 5 ni a s t g Ll u a s:
u*lu. .%pp. 960 no.O 0.= 3St. 198.2%
Table B-1 (Cont .) lei, Cua.ti.L =r TCaLr L e nn masin - plScuence , uppnet rne SFCOND OHaPTfD PLOWIDA PoeFM Cn8PopaTina DVFpaLL anTTne CneF Cnmane377 StanCTuwt. Stunt af CRT5Tal. Alft;n Pntru plant .
========mumPla op I nn i v a nnat 5======== ======= Pts Soisa>E mtTth====== ====tFT DESCMT==== ****Def DEICHT=====
TaIng 4 alam paNCF STD l>LT total. pF44/u2 YntaL Pransa2 FamgLT mfeu = nla%TILinar tsmlu. SPP. 25. 3.6 0.= 25 9.62 cenF# TamalDaCFa U480 sP. 74 10.9 0.= St. 20.04 Sunnunte pisDenPHORA untD. SP. 25, 3.6 0.= 25, 9.64 SunoenFa noenapunpunan HMID. SP. 340, 320.0 0.= 255 320.94 ramlLy nat.LlaP%EuplDat Matt. law 5EHDt3 SP. St. 1.5 0.= 25 12.43 DanFR IsnPona FaplLT ANTHuulDAE M4 unIn. SP. 1070 Ib2.0 0.= $66 389.48 8 Fa4tLY 10076IDaE C8 unto, sp. e46 123.1 25.= 204 71.56 I FastLT SPMaF.m0maTIDaE F# uwIn. SP. 102 34.6 0.= 25. 13.68
'E opDF# a*PHIPnDa ranJLT apprLISCIDaE t#NIO. %PP. Sul). J48.9 25.= ISS. 245.45 FaulLv s e P li no t D a t-omin, sPP. 407. 50.2 0.. 153, 63.60 Faulty anegust 9480. SPP. 3859 458.1 204 = 764 116.06 FAMILY BATEIDaC Hulo. SPp. St. 7.3 0.= 25 12.45 raglLY Capht Lt.!Da F.
443D. SPp. 353. 28.8 0.= T4 2F.22 FantLY CownPHilDAF UNin. SPP. 121 St.2 0.= St. 24.22 FamILv Leutnfun DaK . 25, 9.62 88Nin. SP. 25. 3.6 0.= ' FaulLY lit.JEnnWGilnaE , 102. 18.50 UNIO. SP. 102. 14.6 0.= FAMILY eFLITInaE 25 9.62 UMin. SP. 25. 3.6 0.= - DenFm DeCaPnna r au f f,Y HIPPOt.TTIhaC nIPPnt.vf L Pl.p puaCaMTMa st. 7.) 0.= 25. 82.45 . ramgLy ricip lu s, nc..io,s sp. as. 3.6 0.= 25 .. 2 FawlLt PggwuTMLklDal Pi.. aa sP. 1s. ... 0.= 25 .6, qD$) r;v 5:'iD r pa D F a n., [bin gy j}N P...r.ssinar
s. =u y.g:J1, as. ..., -
,a. L. a . . i n. ,a .T,a,na r, . s , . .t. T. i c. 5 ... 0.=
~~f- -~~
- n,,u. sp. 25 ,.6 a.= 2s. . 62 5.. .n. ... . .. ara Tla ca.io a. zn.a Si. i., 25 25 i .2...?
4,
...,n. s,. 1s. 3.6 - .
m _ _ _ . . _ _ . _ _ _ _ _ _ - - _ _ _ _ _ _ _ _ _ _ __-_ _- _.___________.m_m
1 Table B-1 (Cont.) CommLLL *FTCALF & EDOT 19f9 SASI4
~~DISCM ANG8' RFPok? 70# SEC0eD OUADTFS ,~~
! enTTne rnme. F',ub l D A Pe teF M CDePORATION OVEdSLL 00 mmh 4fff stepCTuul STUNT AT CaySTAL algte PHeEn PLAuf . ~ ========4Umpth DF InnlWIDUALS*=***=== .==...=PER $0HanE ptTEp====== ==== WET WFIGHTe=== ===*D91 WEIGNT*****
TAION 4 NFat PAhCE STO DEV -70748, PFAN#N2 TOTAL mFAN/m2 , Sunnunta nFPTANTIA UgIO. SP. 2%. 3.6 0.* 25. 9.62 rufLum FCN l gfif 3Fa m A T A 2.292 0.32T 4.48T4 0.9997 UNIU. SP. 362. 14.6 0.= St. 20.04 i N G 1 1 1 t3l I to k u 4 9 3?e) k_ l) c c- _ __2
~~_3 t m_m~~
~~{ c_ 5 p~~
~~._ca u$3.'LJ P~~
e
I. 4 a i 4 Table B-1 -(Cont.) Cflantbl. ** ?C A LF & Etrnf 3979 neste = niscuseGE WFPONT FDs . SECOND tesapTt.s auTTom Cnur FLoulpa P'Bute OnePomatlee OVE#aLL ComesaglTT STRUCTUpE STUbf af CRT5?sh MIvFN Pnutp PLAST =
........m past,R nF janIVgnyalg..e..... ======= PEN $0 Haag, pg,ygme=e ese .ee*WFT WEfCN7==== ****DDT WEjCNT=****
Ta arig e at,a g panGE STD DEU TOT al. Fram#m2 TOTAL pfAN/m2 TUTab 97599 12584.8 #SSA.= 2l054 4237.33 8T2.842 24.592 S9.0396 0.S40S i l P4
~~I CD i 8~~
~~! PJ LA s~~
i I t 4 h i
e 9 9M S E DS 4% = 9 m 9 O j Nmd SE m M > e e p e-J -e e e o m O mSe EW e e e se 9 e es um e o e e e SW = c 9 e G i O. W e 3 O a -J m M e e M
= se E O- e e e e O m - eC = * # e e- e e e e e 1 e o e e o e I 0 > O O O e M M b
~~eN GE 9% e e & W W~~
-E M e e e F Ee e e e a e gW e e o e e ,
un e O 9 e e ' W m N 8 WJ m e e 1 se e e l e- M M M M e
~~- eO e O e e e E g- o o e e o -~~
~~e e e e e m >~~
> M .J m a - ep memo O em @ P Oe p SF 399e M W G 9W O
~~m e = @~~
~~e mm~~
m SP e FP -mes m 3 ee3 O d m e m e Pm me=M e y a e e o e e e o e o e e e o e o e e e e e e e e o e o
~~,3 O~~
e e m = Mm amOm e em a e om e 4* Momm o eeC ep- M M M = = Mm Mmem e eM = m en e em same e
=
~~c m M = a eee M = W SS~~
- eW Fm W- * * * * *
e e * * * * *

e e ** e * * * * * * *=
~~- Ca JW O~~
e M e e e me *cem m em M me a -e meem O = es eM m cp eMMO m C -J 3 e 9 e e M em eMMO M Oe M O m - m a m W em CW e =
mm M M e m.W m m E-e C peu bCam E.e - ==W COe e 9 9 9 e a ea eeee e ea e e ee e ee eaee e e o e e
o e o e e e o e e e o e e *
e e e e e o JhCW ans e e OOOc e 90 O e OO 4 OO OOOO O e U = O e a O O OO M p W- - 5 M e e M >
~~= m -Eke hC.W b3 C. 1W . 6 WC B e Ja.O J -~~
3 We Ee O e e e e m Me emme e ce a e e e SM e e p e eM e e Mmme e e o e O e e e e e e e e e o e o e o e o W en E eE e e e e Se OOMe e OO e O 40 e 4C Oc#O M M O 39 e O a m e em M mm a m = E mW E GW e e M e en M*De eN e N e e m a O as e E W D3 6 J- t kU e 3 e e e o e e e e a e o e e e o e e o e e o e e e E e 0 O e M M w c => Mo Oe=M Mp m e em e e e*O M e se Cm O m Mm me emMe
*##* O e
w e a e O M M eM m = e e e a e = e OM = M. M M e m M M e m I E E O M i = e i U m M N [ E @E e l . mb U gm M m = i J m 0 er = W 2 O O. P h*
~~W J~~
= ebc ese W s e E3 -mm WCO F d e 3 W C WeJm W EU= e. C M 4 e e WJ@e-md e =m3 J WE C# 4 O eC: cm O =re 6 We ema um e. :1 O m ' W =
~~QUQm.heu wmW jew~~
=
~~J h' e C, ces mV3 e1 82= Q-er2 m -OS U4em 2 2 kJ e~~
= 3 CeWJOm&m> 34m weWUM mOE*
M b e O JJmaa m J. b -= 2 d- *= M CE O.fe4CJ6= g I ee. e. , F h.
.e s. . -u- m.. .J , .E em . * - e e W .a..e .. .e -e c, .ee==.J. . e .m . - eJ.. ,.e<. ,me m J ., J . meJ= J e m.
~~l 8 e m W~~
~~= e e e - -~~
~~mer CJ e a. cr.d C - ac Ce& r...,, a=< 2= Oz w C. sC ou-,. .* -e m. em, m-c . e. .J . -s,, J t = l %v~~
~~= t.~~
~~J e - e o, o av es e& emzJ-e eda m,m -c o c .==~~
. me We .e JcQu O e d. m. u - me e u. .= e me . . em - == Wm m m. mO m,- . . . . =. =. v, =. . .=m. W .m e m,- J-..e,.u e -. , . m. J o J t- = J .- J - - , m e - - , - ., . J = J e J J..J , c. W .J==JOJe.Jo ..J-J. m -
u= ,e = . , m. . eO .m m m a m m = = - - m e a a r a e a s e a A ,u a e
~~. se a~~
~~a a s a se n~~
~~.e .e ,e ,e .e .e .e m e e mm e e m -~~
~~- m- O J J J J Ja e M ek e - - - - -J J i~~
~~g e u g .e c. - .z .z .r .x .z u~~
~
~~Ti,D D D, V, J! I-B-26 r J a%U~~
~~d. r. 9,JLL d!J )J@a o '~~
l l
Table B-1 (Con t .) CommELt. mETCal.F 6 EDDT 8979 Rasim = Cngfant arPopf pnp TMlao cuanTEa 80True Coat FLoktpa Fowl'R CupPORaffnw quEnaLL CDa*44ITY STouCTuME STUDf af rev5TaL elvEn Pnuta PLauf
======= muuPtn OF I ND l W I DH al.S a == ===== ' ======*PFR $0paaE alft#=**=== =*=*sFT WF.lCHT==== ====DAT WEIGHT ==***
TAIO" 4 "Eam samCE 370 DEV TOTab #Eam/M2 TOTab mEampet FAMILY nomiditoat naPLOSCOLhPl.HS anmHSTUS 102. 20.4 0= St. 28.!. . malutaEIS Sv. 229 4S.8 0.* 853, 63.48 SCnLOPLOS WHeda enn. 137.5 25.= 382. 145.04 FAMILY nwEgitual rewEnla t uhlFnumIS 25. S.1 0.= 25 11.39 FaMILT PasaDwgpat sulCIDta PHILntmat 458 98.7 0.= 255. 102.01 adlClura TaTLHRB 560 112.0 25.= 358 137.04 apictosa Sr. 25 S.8 0.= 25. 31.39 PanaqmlbES SP. 433. 86.6 0.= 204 79.12 FaulLy Pwys. Lou 0Cloat ETEngE MFTinnenoa Ta. 15.3 0.= St. 22.70 pg FAMILV POLI 4DIDAF I LtPinastipla ComuFNSaLIS 25 S.3 0.= 25 11.39 og LLPluG40TuS $P. 76 33.3 0.= St. 22.74 I FAMILY SahtLLIDaL bJ CHnWE DHNFMI 200 56.0 0.* 127 58.07
*J FabalCla %P. S35 307.0 0.= 255 92.42 uMID. SP. 255 50.9 0.= 102. 47.64 Faugby sa>FLLaallDAE saMELLawla Wut,Cawl$ 153, 30.6 0.= St. 23.38 FangLT SCALIrulGalDaE M t005 COLE t LumCISETA 25. 5.8 0.= 25 St.39 FaulLY stePULipat U480 SP. 1604 320.9 0.= 1401, 600.l2 FaulLV SP I HN Illa C PamaPe1040$ Pin Pl4Nafa 255 S0.9 0.= 127 54.9)
POLinosa *PR57tpl 540 112.0 0.= 407 167.56 PulO905rin METENonaa4CHla 2a0 56.0 0.= 17R. 15.88 , usin. AP. FaulLT %78.Lt0AF 25 S.8 0.* 2S. 18.39 II\ D
$ ' "[d~l y Oy FNOGn*E n!$Pau 2a0 56.0 0.= 878 88.13 "DJQ . ;d O ..s ,i f \
tsIHn4TOSyt.Lis SP. 76 15.3 0.= 16, 34.16 "@ %=# '8 d ,G 1 " l # STLLIS SP. 2012. 402.3 St.. 1648, 786.75 FantLT Tree mp t,03 nae Lv$tLLa 4Lna 164 352.0 0.= 444 199.70 PISTa paLeaTA 25 S.4 0.= 25. 88.39 STmEkbosoma Hantuamat 102. 20.4 0.= St. 27.90 , PMTLua ent,Lif3Ca CLa5S A"PMl4FHpa 0.827 0.025 0.0044 0.0173 FaugLv 15tugnCugTnginaE 85CNNoCulT04 P& Pit.LOSHS 121 25.5 0.* B21 56.94 CLa$s mBwaLvla 79.895 15.e39 57.6674 31.5335 Latvirawofue unwrngs 25. g.1 0.= 25 33.39 fantLT Caungripar CaeDIta=>wa *Loelnaga 16 15.3 0.. St. 22.74 F a m i t,Y
~~T T i t.10 4 F hwaCMthM4Tes SPP. St. 10.2 f~~
~~25. 33.95~~
. \
e t 9 0n 9E eE G% O O em es aJ ea @ *
t= m3 to e e m as S e EW e e ea OR *

3w me n at C> W O 3 C
~~a > a:~~
== Ee O O E C> O O > eO ** e 9 t= ** d e e e $ re e se em 9
~~8 fe GE 6% e O~~
>B e e Z4 e e We o e == a ** a=
In: se . B (al .3 se e e 9 > em e
~~> 9O g=~~
3 0 De a e e O M . >
e3 as c S > e 8 0 el e e pe e O aeme e ee ee e e e e se e e tw a p 3 9 e2 n t m fe re e m ast est a se ee m =*
ast 3 m

4 e t 4 9 e o 8'e e o e o e e e e e o e a e o e o e o e
~~& 9 e2 e e m se at ce at a ee - en e em m os se == =e en a= a =e a=~~
8 e> O e se en at es e 4 se se se est se ass a= a= ee a= se se en == J* = l 3 e ee == N l W 9 R i e aw I W == e4 >
> CE e * * * * * *
e o e o e e * * * * * * * * * *

2 ee a=ea e ** e e e ==ome art WD e art e e e e e am e e re O e C >J = fu e o fw re Wt O e tw re n y= n fw ft ce ce es e fe ce O 4 f*
es ee Oh fe en ce se em # 5> == a w d O ef* *eO S&> * * = 7 e: EE C?e 5 9 8 8 0 0 9 8 9 9 0 0 0 0 0 0 0 0 0 0 8 8 9 ea m C u a se a e e o e o e e e e e e o e e $. e e e e o e e e W ** O e O O O OOOC O OO OO O O O OO O O O O O La > > E es em a e as 5 46 m: . C no a&a> e s: C E o Ja&2 as t e2 > S 9 9 e ao se e ce ce @ == se en > en tw an em se se e se se em a e. et e $$ E S E e e o e e e e e e e o e e e o e e e e e o e e e ! E C 3 9 dB O em W6 e O OeOe e ee WD O tr* e art ee Wt e O E @ r 3 a= J E 9 as e a ce am 4 not m me ce e e l O 3 3 9 S - W OD 8 J> 8 fee W G
= c E 4 e e e e e e o e o e e e o e e e e e o e o e e * > I Wt A e It N em se m # @ @S @ es e e Wt @ fie W6 @ e 8'e e e e a e O n n n nn ne n n n pn a n O e n re e .O= em en ee. n - et v Gm a=
~~N 3 E E. M E se = me W e se W ee Ee~~
ial T e e to e4 W h as tai a5 2 e4 3 tad e ; e isdlm, e Q sF. 3 O as W 7 ee == In: as e J e W O e C == U > araml == C2 e Z
~~#"% Ek as &J=F e em M me J == dWke J e em U & =~~
~~e Whe~~
fa W O == = v e eC W m3 e e J = ek 4 C e r = es e s, J e as C e y e M 3 & e en me e que J u e J (b == 2 J to # J > e e C====

W & =9 e3 J e a a 2 O

O tr. 3 J W & as Te3 & 4 oo == k e' O C 3 == > J & C e6 hJ e C ke: "*
C == 3 J == e C e5 C eC ZaTZ4y e em O3 J en en e>= 0e eC e# 4m B O kCEeJTeE == & = 4 e e e k *
C == 8 J U T e te

aeJe2 e CCtu&C4 : * : e Q 3 sei = W e O O == at U WB & J J J J me a as J B J a= & # 2 m e e == J > C C .e *C4& = ace:
~~& e &OA6 e 7 1 eT 1 V J es ae e _g a~~
~~0 s a w we&a ;ey a OC w;m=ss JWJa=we: m==4ar=4e 3CmaF 0 == J as J r : aee JJa=C 2C.3 C~~
~~&U& E > e =8 0F 4~~
C C W & ab d O 2 F U D y es se em me y 3 y T ta: a r == a > g e C e & k C D W Ce e oe ** * *4*
~~2 5 sa - B =* u &&&& a= US 2O e em a eC a= a>UJCCC3 7 - 2C 2 N~~
~~H M E 1' e= W h hee al 9= e> as a J e == Ce J ZM e e3 *#~~
Rb to en > W Sm 3 ef > e > e se e a & F > me > W == em 2 at en g > e > J em c = > sm W3 e4 "e N >e 3 as se 2 l EE S E W9 2 t% 2 49 OE J2 gg WO m3 0see3 db me == e2U em e e JseZ J a= b J W W WesW JmeE J e W == J C E se J Q meJ W J. C == J C k me JU as W to ec # 3 ==
W R E W 9 E S E W F W 3 e3 E 3 a5 2 e e2 7 E 9 0 m e e e e as e as as as e as e as e4 al J Je E e e W w w m w dw w w w w w w w m 5 5 nevo u v s em a r: e e =csa a a e a o -> 0 e Je=C s ma C e se me ea = J es e e f0 eC eB W E Fe &c
~~e. u a?~~
r-s-28u.-liilu JVu - dnb d J _,
Table B-1 (Cont.) CDhht LL ut.7 Cal # & EDnt 1979 SaSI4
COmfant mEPnpf FHR T4300 QuaPTIR 80TTum Cou t. FLukIDA P4et W CnaPO4aTIOm OVEpaLL _
~~ComeneITT SimuCTunt Stunt AT CutstaL pgvin PosEn Pl.agt~~
=======*gunste or Ip0lvinuatS*======= , =======PFm 50uanE m6TER====== ====wFT ut3GMT==== ===*0RT WEIGNT=====
~~TaIOg a stam ma4GE Sil' 0+ V TOTAL stampm2 TOTab REAN/M2~~
~
Fa4tLY [DOTEgDaE Weln. SP. St. 10.2 0.= 25 13.95 Fa4ILf SputEnonaffDat , unto. SP. 255, 50.9 0.= 102, 47.64 ORDFS A*PMIPupa FaulLI a=PALISCIDat 4=10. SPP. 76. 15.3 0.= St. 22.7e Fa48LT 48P48LOCHIDat d4tD. SPP. 153 30.6 0.= 76 31.20 Family asPITMOID4E u=IO. SPP. 015 363.0 0.= 433 370.00 Family anatuar UmIO. Sep. 1350 269.9 76.* 506 222.43 ed Fantog RATFIDaE 8 4=10. SPP. 25. 5.8 4.* 25 Bl.19 C8 FaaILT C4PW6LLIDaE 8 b# ymIO. SrP. 255. 50.9 0.= 127 59.72 W3 FAMILY ConceMllDaF unto. SPP. 1906 397.2 102.= 3299 510.76 Fa8ILT LILJEmneGIIDAE uggD. Sp. 127 25.5 0.= St. 30.01 FaulLv Lislama5SIDaE UeIO. SP. 25. 5.3 0.= 25 13.39 FamILt mELITInaE uwID. SP. Se6 187.8 St.= 255 03.69 FauILY PHt.tamTID&E unto. SP. 170 35.7 0.= 127 55.79 FantLv PwounCFPwar,Ipat nulp. SP. 153. 30.6 0= 76 33.20 FantLT PquTOCEmEIDaE 4eln. SP. 302. 20.4 0.= 102, 45.55 FaulLY STF.wuTMOIDaE
u=Ip. sp. St. 30.2 0.= St. 22.78 nwnFo nFCapona FaegLy aLpHFIDAE ALPwFuS mowma==I 25. 5.1 0.= 25 18.37 aLPMEUS SP. 25, 51 0.= 25 13.39 FaeILt ulPPOLTTInst n ! PPol.T T 5 PLEUR 4CANTMa $27 25.5 0.= 76 36.01 .
MIPPOLTT6 SPP. $27 25.5 0.= 102, 44.18 U=to. SP. 25. 5.5 0.= 25 33.39 FaaILv gaIInaE PtLla muTICs 25 5.8 0.= 25 88.39 , pamILy p a ce'w l u a r . i j u Paco.ns ,P., F a n g s.y p i emor n> > II,a 6 229 45.. c.= i?.. 2 5. n . [] ; iD ' i+ dlm, h,- L i 6 Pia.isa SP. 59. 10.2 n.- 25 II.v5 i L {\d ungo. SP. 2 T. 5.5 0.. 25 St.39 F a 8 8 8.y PowCFLLa4In4F, Pt.TuuLISTwts aumafd5 St. 10.2 0 25. 13.95
l Table B (Cont.) CommELL #FTCALF & D I,ny 3919 ma5 3 m = Cn%TWf t, M9 Pout *ne THIRO SUA8?fP entina rohr D LrjalDa Poeta CosPomaigrim oygpaLL C"madutif STpHCTupt STUNT af Chisfal. PIVtp Potts PLauf ,
========mUanEn nr 3 a n g y I Du a 3.s====== == =======PkA 50 Hang mEfta====== ====uET WEIGHT ==*= =***Def utlGMT=====
Tanne h mEau ma4GE STD DEV TOTAL Pt.ag/m2 70 fab agente2 PF.Tenbl5fMF5 SP. 327, 25.5 0.= le2. 44.83 Fa8ILY PenCtssspat a un t or a Te k S t r a t.Te lCU S St. 10.2 0.= 25 II.95 raetLT aa*Ta4IDar EumfPagesPtOS OfPplSSUS 25 S.l 0.= 25 38.39 mropanopr Paceaant 25 S.t 0.= 2%. II.39 me.orawnPE TEsawa 25 S.3 0= 25 38.39 at0PagnPE bP. 204. 40.7 0= 36 la.36 U=In. SP. 342, 16.4 0.= $7N. 14.24 Sunnan,e mata4Tla Pnsi Laevat $8. 10.2 0.= St. 22.78 Sumoans e Rt.Pf amfla
**GaLopa St. 10.2 0.= St. 22.70 P4 I PMILua LCMImonfumafa 26.016 5.285 0.3030 1.6166 QF U4tD. SP. 255 S0.9 25.= 16. 18.08 8
W PM T L.U E CM090aTa O Cha55 45CI0taCEa 37.000 3.560 4.5999 0.9806 UNID. SP. 229, 45.5 0.= 204, 88.94 i C3
~~@=D -~~
~~Ehel G-a~~
^
~~PJ5D~~
~~.==~~
c=m ~ E52D L en
4 , 4 b Table B-1_ (Cont.) CDanti.L nFTCAl.r & EDDT 8979 RAstu ConfanL DEPriNF Fng fugpD OUARTER - moTTom Cout #Lt)mIDA POwFN Cou pe)R A T ION OVERALL CommugsTV STuuCiuwt Stunt AT CatsTAL stora pnsta Plast
........euants or 3 mo g y g oun ts........ , .......PER s00ARE METER-===== **== MET mEIGNT***= ****997 WEIGNT*****
TARO 4 N MFAN k a nGr. STD bt:V TOTAL mEAm/m2 TOTAL mEnsin2 YnTAL 34301. 6060.2 3369.= 19784 3897.98 ' 400.429 08.606 153.4926 30.606S 1 b 00 , 8 4a I i i 2 9 9 % e
e e t 9 GM SE PR 9 % O w > mWJ Sa O e O
~~@ kJ ke O O e mae EW O e~~
O e e eS WR SW = O 9 M Om W G R C a kJ m en O O E Ok O m @ k 9 O O W G j Sp 9 9 e o i g o e 9 O O e m 8 eM GE i 8% 9 m m ME O m p Ee O O w Um o e e
~~mm O O e W m 3~~
~~WJ 9e F O 9 Sk M M m~~
~~> SC O e~~
M o M e E G k e 8 O O M J O 8 > m p e On M e em N & 49Ep@ f M W 8 9 d OO m N % NoeN N N OO # W M MOOM P M e O we e M mm e C e3MMN d S 9 04 o e o e e e o e e e e o e e e o e e O 6 0 e e e e e o e e o e Oh M S m 9 43> P e p O PM p e se e e e*BMS 9 9
~~& 9 GC e > Me e MM d epmde =~~
9 G W P m e emMM M M Wm m 3 9 GM e a e b 9 5 3 8 4 Em Me e o e e e o e e o e o e e e o e e e e e e e e o e
~~> Og Ja e o e mapem #~~
O = oE Ce e e e emme e e e - Me e p we e e a O N O N N O eO@> # D N @ ON N N dN N & Ob %*f C kJ 3 M P m e=Me W de Cd M e em e M =
==
RM mew m J CM Dec E&- ==E 3 e e ea e e aeee0 0 e hCsa Coe ee e e e e e e e3 ee e e e e e e e o e e e o e a e e e e o e o e e e e *
e JmCW E V. S *

p*OCC C O e W

OC O O O OOOO O O O O OO O O OO O O um b s mM e.
M32e ha ' *Om CE ' s&B - 0 I eCQ R e Ja&2 e t e a @e=#*
~~4 l~~
J > S t Om m ee O MeSe M e p o ee e eem eeo c e e AM e e e e e o e o e o e l W eM E t F e e o e e e o > m W G S ge op p m = e e s .e O O m O Om e m e e em em e e e PaPen ende a =a 2 0 4 M e pMmM e e a e pc G SS S S m e W 32 e JM S eV 4 L 0 o e e o e o e o e e o e e o e *
e

e # *

e e o e e e e m #
~~m seem a M @ e km @ e MM c M 4FeEm~~
~~> S Ce e @~~
~~enne e~~
M w q e M e MN n e weste O N M 9 E C O N O e N D de m O m M e Me dove I - m m em r
=
~~r l = a S O M~~
=
u M ME ma Em 32 W e W. Os = W m ebC e W W kmb W e e e 2 a e 43 W W & O O W 4 y= em WeJw W e CJ ekwJ e w e J w *WE > M -1 C=me O DEUW We WE*= J C42 *EC
b =J A =& W = WUewe 46 EMck 3 WJeE eJJ & 4 =7 e *Op = > 'a u e ; = =C=- eM E *2 >
~~M Jen J e RosC a~~
~~=4 e M~~
~~C W Z e e X& 4 JWCW W M3 = c*=WS~~
~~&=> E Mrae e = =. =C M A J ==0&OM == e2 rFM2 C&mz=1.e&~~
~~w. = F A M# J# 48~~
*J J= >e e e WM M oekeek ee&W Wee Om et SJ =Oeeee=&
4 a ma 2 W B& sa e W&h=Je wW e a* a && m L* raampM143 4W4=43-se 0 =W RM Fe e e M e & J . F & ewe a d = ae v. u. e r : =M 1&. F. Tem D=e 3maEeC=CF *WeJ
~~%# E e~~
~~E J e~~
=
~~k e Op CW 23~~
~~=U mesC.~~
~~e3W>ec*U>e EUWumzm we: -JaCrwM WG~~
*Ja.Com eCrOCE===O E
~~Jer w & J~~
*M=4J b
~~Z WC 50 >= JoCu =6=C &~~
~~.e . - -~~
~~W U o e, CC= = = U~~
~~===U U e, =f 2, .~~
~~u .= W= W. - &M== &= E ,-e-~~
- Mm m, ee W-o m. .- -e-J.J - -=-e. ,- ..,,eJJ.JcJMJose&=J J,e , =. M= ., = W ,Joc_Jo. J-eJ. JkJ.JoJoJu=_JJJ - = , =C .u.
~~e o .. &.e e e e~~
=
~~m. m. .~~
= . .e e .e .e .e - - .e .e .e .e .e - -
~~e 30 2 D 3 2~~
~~.M =M Mu M~~
~~g Je e~~
~~=> C J J J o --~~
~~e e e z z z~~
~~-J zu v J~~
m > & e .& & & & ce g g yd - D D I-s=32 oa w]J\WJAINly rubJ e
Table B-1 (Co nt .) Comett.L #FTCaLF 6 FHut 8979
. easle = OISCusmCE stPnst ena THIRD GuapTER POffne CosE fLuklDa Poeta rosPneaffnu ovtasLL ,
~~C0=an9fff STpHCTHDL STUDY at ChT57aL wivre Poeta Pt.647~~
========muset# DF I m 0 l v i pu al.s** ====== , =======Ptn squapE pFTFR====== ===*wFT DEICHT==== ====Dm7 utlCMT=====
TaaOg g agag BahGE STD htV TOTAL mbampu2 7074L stampn2 FaulLT SFmPULIDaE ugl.a. SP. 25. 3.6 0.= 25 9.A2 FaulLT S P i nu l p al-Panaspiquusplo PImmaTa 357 S0.9 0.= 153 64.U9 PULVCoas egn$TERI 76 10.9 0.= St. 2n.v4 PWin4JSPI4 MEtgannpanCMin IS). 28.u 4.= 14 3a.we SCOLFLFPIS 50uamata 16 80.9 0.= st. 20.04 STuthLn5PID PDhtDICTS 280 40.0 0.= 802. 44.86 FaulLV SYLLloaf EnncogF p15 Pat 25 3.6 0.= 25 9.62 STLI.Is SP. 153. 21.s 0.= St. 17.57 PMTLum ROLE.usta CLaS5 a"PHlarupa 0.076 0.011 0.0662 0.0095
~~,y Cha55 ca5Tanpuun 4.800 0.506 2.9832 0.4862 i~~
ga FastLf a CT F.nCi m I D a C I aCTEntthe CagaLICULafa 434, 69.8 25.= 327, 30.80 La Fa'ILT M a u l 40Flo at: LJ Haml40Ea sP. 255 36.6 0.. 353 Se.SS Fan t! T CatCIDaC CaECu" SP. 229 32.1 4.= 318 66.98 Faagt: CawcpLLaminas: CanctLLawla seTICULafa 25 3.6 0.= 25. 9.62 FaetLT CEntiwitnaE ntTIue vastue 351 50.9 0.= 306 112.93 FaulLY COLHantLLIDat
*ITats.La 1.ngaTa lie. 25.5 0.= 102. 30.90 Fa=JLT PT#amintLLIDar 000570=la LattlCATA 25, 3.6 0.= 25. 9.62 Onnsinala SP. 2%. 3.6 0.= 25 9.62 Fam1LV VITuleFLLlhaE TF!mo.%T0*a sp. La 2. 54.6 0.= 280 103.36 vlinI%tLLa FLo#I0ata 229 32.1 0.= 229. 86.62 PuTLug aarmenPooa CLa55 Consfacta 12.010 3.124 1.0451 8.1200 SuncLa55 Copppnna OmnFa CALagnlua 4430 SPP. 25 3.6 0.= 25 9.62 ,
nanta rTCLnPogna simio SPP. 25. 3.6 0.= 25 9.62 suaCLass nSTuaC004 3ge.62 - uutn. SPP. 4074. 582.8 327.= In10 Suurta55 Clww 3 Pe n t a FastLT
~~a r.a = I n s t O~~
~~.aLa...s s.. St. 1.3 n.. 25. i2.4' D D i m,~~
~~Sn.Ci. ass -a sC..si o.nF. aCa lD f w1 T~ - yu~~
~~.,I,io.~~
~~sn P....a s . ..,. S. 2 .= 24 9i.e. -.~~
~~0. n. . a . . . i r. .. a e a ale.T Cap 6 Loinst: s , ,~~
a in. 5 . 25 i.6 0.= 25 9.62
l 1 i Table B-1 (Cont.) C0thtLL dFTCAI.F 6 EDDT 1919 eastm = utsCgance ug Pon? Fein TMIRO OUARTED n0TTum Cour FLUSIDA Ponte ConPosaflot OTEmaLL COemuutTT SThuCTunt STUDT af CpTSTab AIVFD Ponta PLauf
========4tsumEA 0F ImplVInUAL5.*====== =======Pgm SouaPE *f7ER==**** ==*= WET WEIGHT ==== ====Def #EICHT=====
l
T4104 m *Eam panCE STD OFT TOTAL uFAP/m2 TOTAL NFAN/N2 FAulLT Con 0*MIIDAE H410 SPP. 25 3.6 0.= 2%. 9.A2 FAMILT #FLlfinAE U41n. SP. 25 3.6 0.= 25, 9.42 F44tLT P0lHICERIDAE stain SP. 25 B.6 0.= 2%. 9.62 nuotu ut.CAPub4 F481LT CALLIAmaSSIDAE d4tD. SP. St. 1.3 0.= St. 19.25 FantLT PaGuwgD4g PAGUud5 SPP. 2%. 3.6 0.= 25. 9.62 FamILT . PlaguTHERIDaE PI44tga SP. 204 29.8 0.= 802 42.6u H 4410 SP. 25. s.6 0.= 25 9.62 I FAmILT P'le CE LL A 4104 E to Unto sp. 2S. 3.6 0.= 25, 9.62 I F A a g e,T Pw9CFS$10aF LJ aantn6ETER StauETn!CUS 25 3.6 0.= 24 9.62 A F44ILT 8487winat 4EnPawnpE SP. 25. 3.6 0.= 2%. 9.62 Sumneoto garagTIA 9430 Sp. 25. 36 0.= 25, 9.62 Suenante M*Pfa4TIA nuaCHTomau Znt.4 St. 1.3 0.= St. 89.25 e tc A Leip a 25, 3.6 0.= 2S. 9.62 Umsn. MP. St. T.B 0.= 25 82.43 4 9 O '
te) O I 1 I R 2EED c~ e
4 Table B-1 (Cont.) i9., CUsetLL m87 CALF & Ency Twspo OwaaTEA SASim = DISCMawCD REPom? Foa FL0 KID 4 Pflutp CnePOW Afice ovEmaLL , 80TTum CneE CismengtTT StauCTumE Stunt AT CAT 5TAL RIVER PosEn PLauf i
........eueste OF ImpIVfpu4LS. ..==== , ......*PFA Squant stTD.p.....= ....et? ytICNT=*== ****OST WEIGNT**=*=
~~TOTAL, *LAN#4, TOTab mEampa, 4 m PLA4 RaNCE STU PLv~~
~~, ..; Th104 T.T.. ...... ...... 1 4~~
~~4 M l to 8 W W i . t~~
~~, l _.~~
k e 5 m ( v . _ . . . _ _ _ _ _ - __ _ _ _ _ _ __ c-- - v- .- +- *e - - - _ _ _ _ _ __
/
t Table B-1 (Cont .) CDhetLO 'FTCalF 6 Enni 1979 MFPO67 fue FOURTM Ogapff B , PaSt u = CathTRnb oggpaLL 007T48 CopF FLOpiba Pnwpe rosP0matgne C0eru4tTT SteuClukt Stunt af CnT57ab plTFR P0mLR PLas?
==......uumero 0F lupITtopaL%=== .=.. .......Ptn SQ"att pFTER=..... ....mFT WEICMT.... .... pet WEIGNT.====
a se at eagGF STD I)ET fnTAL PFab/m2 70 Tab utan/m2 , Tason 195.902 30.380 49.4220 17.0044 , PMTLU8 Pom1FFRa velp. Sp. O. 0.0 0.= 0. S.n0 0.025 0.na5 0.0306 0.0069 , PuTLun PLaTTurL814TMES Uml0. 5F. 76. 85 3 0.. 58 22.70 6.058 0.080 0.0302 0.0076 , Puttum asChtLalmTMFS U9tD. SP. 236e. 413.6 u.= 164 327.40 PMTLum egetaTImEn 9.407 0.nel 0.1968 0.0392 , umID. SP. Stel. 336.8 370.. 506 195.93
~~>4 3.807 0.628 8.3904 0.270s '~~
8 PMTLUE SIPueCUL4 CD utID. SP. 450 98.1 0.= 200 122.92 l J 42.508 0.500 15.6353 3.1273 Puttue asstLIDA
'ch CLAS5 OLICncuatfa U9tD. SP. 2266 453.3 357.- 535. 72.92 CLa55 PnLTCuatta FadgLT 40FMICOLIDat antaltnba Cu!> tat 4 25. S.8 0.= 25 St.39 FamILT a s a nts,L t c a t ana0FLLa totenLos 102. 20.4 0.= St. 28.31 StatSto=Fasscus puDOLPNI 16. 15.3 0.. 25 13.95 '(C}} -- 9410 SP. 127 25.5 0.. 121 96.94 Q FaeILT CAPITELL30aC 507.44 i- CaPITELLa CAPITaTa 333. 66.2 0.. 25%.
~~25. 31.39 (E$ )~~
t;--- MLitenra5TUS FILIF0aul5 sternes%TuS CaLtroengtests 25 4304 S.l 060.7 0.. 0.= 2037 109.08 c;1C3 anTn a5 Tits SP. >S. S.I 0.= 25. II.39 SCTPHOPe9CTuS PLaTTPROCTUS 7e. 35.3 0.= St. 22.10 ut!O. SP. 333. 46.2 0.. I?u. 13.34 FamILT CustTOPTFeIDat 5.9 98.39 Ibb53(d
~~' T_z SP30CharinPTEpH5 COivason Faa!LT CImmaTHL:nat~~
25. 0.. 25.

flig) ,
TuseTE SP. 2640. 529.7 255.. 3044, 300.90 Nm" F a u s t.T fuhtCIngr 25 25 II.39 . {}))}) r - ~~ , eaupatsa tamcuteFa et.maTOs(a g s untC.jaels 25. S.l 5.9 0.. 0.. 24 St.19 H*ID. 58, 2%. S.I 0.. 25. 19.39 c__ , g-tEC[ FaeILT FLahaLLICtptnat
~~24. 38,39 Plan =ts aauca 25 S.l 0.-~~
y s2- Famity 6LTCtespar CLTCena a*>eicava St. 30,2 n.. gl. 22.70 . FantLT Gs,%f ang o at b 3%3. 42.we OLIClanF AP. 306 69.9 25.. - f an ts,f 4f510%ghar GFDTis metstPal.Pa 127 25.5 p= 5t. 2S.44 OP=fN.wn-us Sp. 25. 5.8 g.. 2%. 18.39 a
Table B-1 (Cont .) Climarl.l. *ETral r 6 ton 1979 sa51m = ComTRub DEPopf vee F0HATM QuapTFD FLongpA ponta cnePneaTIOh nvEpaLL POTTno coal. COmpumITT SfauCTumE Stunt af CPysias. p1982 POWER PLam?
========pumptR OF I nnI V ! 0H al.Sa======= ======= Pep SQUaNF >FT6R====== ===* MET WFIGHT==== ===* DRY mEICMT=====
TaRom 4 Ptah RapCF STD DET TOTab nFausm2 TOTab mEam/m2 unID. SP. 102. 20.4 0.= 16 33.20 FamILT LuomaletaEIDaK Lummelstuts sp. 102. 20.4 0.= 76 33.20 FAMILY m ar.Lg oginar maCB'I.Uma PETTIMomEar 433. 46.6 0.= 333. 139.08 Fam!Lf maLeaul0Al AsinTHELL4 wHCnga 2gle. 422.2 g,= thin. A04.62 epamCMlea5VCHIS anERICata 382. 76.4 4.= 229 100.u4 Um!D. Sp. 2to. S6.0 0.= 204 85.22 Fa88LT MEREIDaE CFeaTenEmFis lealfaBILIS St. 10.2 v.= St. 22.78 CLRAT0m*#EIS SP. 25. S.I u.= 25 II.39 LaE49EMEIS CULWFWI %l. 10.2 0.= St. 22.78 pg nLaLIS aruminafa 1.7 25.5 0= 127. S6.94 5 % Fur gs F al.Sa 25 5.3 0.= 1%. 13.39 De mLPFIS 50CCl4Ea 25. S.1 0.= 2%. 88.39 I *F*Lis SP. 153. 30.6 0.= 127 SS.21 LJ PLAfteFmFIS OumEntLll St. 10.2 n.= 25. 13.95
'd unIp. AP. 433. e6.6 25.= liu. SS.19 Fam!LY ONUPMIDaE OpnPMIS et%hLOSa 3363. 672.3 0.= 2863. 844.49 Family neele!Inar paPLn5ChLaPLOS #00USTUS 12*9 259.7 St.= Sho. 252.55 maleEpEls SD. 16. 5%.3 0.= 16 34.16 $Cul.OPLI5 Dunpa 764. 152.8 St.= 306. 352.45 umIO. St. St. 30.2 U.= 25 13.95 F a
I I. T PamaDelpar selClfta PMILDImAL h64 173.2 0.= 407 150.00 .
a*ICIDEa Taft.oel 255. Sn.9 0.= 76 38.19 pasa94!nts sp. 458 98.7 0,= 229 99.63 untr.. sp. St. 10.2 0.= 25. 13.9% FaulLT PNVI.LonnCIDar . EtM I D A SanGulhFa 25. S.l 0.= 24 18.39 ' nNID. 58 25 S,5 0.= 2%. 18.39 F a mII.y poLymotpar LF PIDamFlpla rnamF.gsal.I.% 25. S.8 0.= 25. 88.39 Fa8ILY M a tst LI. lD a F CHOWL numEWI 1871. 234.3 0.= %3%. 196.76 FadelCla %P. 5057. 5003.3 76.= 2644 8042.42 , thic. $P. 802. 20.4 0.= St. 29.38 Fam!! f SartLLamIIDAE sanFs.laula WHt. Gaels 3e2. 14.4 0.= 255. 183.80
~~. F a~~
~~I I. T SFrPHLipat Uml0 SP. 2314 422.7 6.= luS4. 859.56 FaulLY SPingInar~~
~~. PaBaPMIONf'%PlH PinuaTa $a4, 137.3 6.= 3A2. 160,6%~~
PfAVunwa d*'P57tpl 16 3%.) n.= St. 22.1# . p*InsnSpl* h616woensurpla lu9%. 284.0 2%.* 1%7 () Is sona-aTa 3.. .2 a.= ir . 81%.1347 0 0 Sr....a.l 0/ d 22.7a I $b l/ ;3( [hl9 b 3rve Lospio a.sti.lcTI st. lu.2 r St.
~~- l .~~
p _
I , Table B-1 (Cont.) COhmPLI. mFTCal.F % FnDY 1979 SFPONT FOW FOURTH Otta979 9 maSim = contenL ovEpal.L
#DITOs CnR F, FLopina Ponte Coppopaggon Cnnuum!TY sfeuC7umE sfvos aF Catsfas, alvte PosEn PLauf . ========mumhPR HF 89"lvlPHaL4=====*== ======= Pre SquapE m>TDW====== ====ut? WFICHT==== ====Def WEIGHT =====
a stam manLF 870 DLv TnTaL pFau/m2 TOTab we.awsm2 tai 0m buiO. SP. 76 15.3 0.= St. 22.70 FamILt Sitt.lp a r nuanta Cf.avaTa 255 50.9 0.. 204 80.28 SanconE ptspaw leib. 295.2 0.= 7#9 326.38 nougTH5VLLf5 6P. 25 S.I 0.= 2%. 18.19 SPHaF80%TLLIS MP. 204 40.7 0.= 76 3a.62 511.085 sp. 2623 524.6 25.= 1757 109.13 FantLv T LR* PLI.L10a E . L15 ILLA an.ma 1375 J75.0 25.= 109S. 461.33 PBSta CN15?afa 25 S.8 0.= 25 88.19 PISTa Patents St. 80.2 0.= St. 22.70 Sim*pLosopa Maarmawar. 153, 30.6 0.= 121 SS.28 UNIO. SP. 102. Pu.4 0.= St. 28.31 t4 i PHILUm enLt.u%Ca 0.9702 0.1940 88 CLa5S anPMinFusa 3.070 n.214 I F a pII.T aCa4TMnCHIT0ploaE LJ acamTHncusTuna pyGmara 25 5.1 0.= 2%. 58.39 OD FaglLT IsCanncu!Tnninst 15CMhnCMjInn PaPILLUSUS 407 St.S 0.= 229 97.h3 Class 'niveLyla 44.232 4.n46 35.7321 7.1464 Lat.vlCaa0lps unnf0nt Th. 15.3 0.= St. 22.70 FantLy CawntTleat Cap 0lTa*6 pa Ft nalDana 25 S.3 0.= 25. 11.39 Fam!LT COW P U L t D a F. C0anut.a Sp. .'. 5.8 0.= 25 St.39 F a m II.T n y f il.10 e r, maaCHIDoaftS SDP. 307, 20.4 0.= in2. 45.5%
k. h FadlLY 9HCol.44 t D a t mpCutama sp. 25. S.8 4.= 25. II.39 h-- FaulL ieucasSpaF mucpLa Pyvalga 3%. b.3 n.= 25. 13.39 F au l t.T 0%ThFI0aC nSTpe a t out KTels 153. 30.6 n.= 16 48.04 Fam!LT F6kiPl.n'aflpaE PtpIPLOPa $P. 174 35.7 0.= 327 SS.19
( }} FamILv SF**Laraf gggggj r..wi cra 3P. Si. l..: ..= Si. 22.70 Stat Lt PDwFICua 25 S.! 0.= 2S. Bl.39 , F a u l t.T TFLLl*lesar IELLlma sp. 102. 20.4 0.= St. 21.38 (C77}})
"~ 4 CLAS5 r,a%Tynonna 099.313 118.thi 171.507S 154.3085 F 44 31.V aCT e r,C l % 8 ts &E ?3EC artF4Ciria ran al.f fULaT A #15 163.0 n= la2 200.99 FaulL1 mH LI. I n a * =
~~CL- not t.a %Tutafa 28h. 56.0 n.= 321 65.91~~
~~, Fan!LY ratrinat r>>Ci- s . *ii. i27.3 0.- iaa. ial 0S b~~
F a e l f.T futWinns.lHAF , (b6 P I D"I.a at ut.t a f a %1 10.2 9.= %I. 22.74
Table B-1 (Cont .) feehe l.L Pa'Tf, at F 6 #DDT $919 pa SI. . ComThus. FD P8 pl D eep FnHpTN QHapTp_R DLatWIba FDwt_N CDDPotaTInd HVFRALL 897T0= fome consuMITT $79uCTUkE STUDT 87 CPTKTab ptTth Post.m PLauf
. .... ...mb > 4F R i sF ggngygnyngg........ . . . . .. . P p. R 50napr pptph...... ....pty ugggpt.... ... 3ag egggny.....
mLas panGF STD Dtv TOTAL stause2 Tntab

Eau /m2 Taa04 CetPIDHLa MaCpl.054 200 St.0 0.. 127 St.07 CREPlo4La Ptaea til. 122.2 c.= 4st. 190.0% .
Fas!LT Ct'e t TH i t pe t CFulTMine pH$fapHE 21, S,[ 0,. 21, ll,)9 blTIUm va*Ipm 1%3 30.6 0.. 182 45.15
%Ella apa=%T 21. S.5 0.. 23. II.39 FantLT Critse* P F LLIO a F shaC4Is DaFKa 127 25.5 0.. 127 56.94 elTetLt.a Lumafa 16 IS.) 0.. St. 22.18 FamfLT Fa5Cgnbspggoag pa5C:otasta Lit. lum 21 S.I 0.. 25. St.19 wantLT *anctaELLipaF Gwamphlen ovut.IF0#Nis 16 15.3 0.. St. 22.14 >< eneCImFLLa ap3rten SI, 30.2 U.. 2S. 13.95 i eneGimELt.a A.s&f0Cincts 21. S.1 P.= 23 18.39 08 ma.-CIrsFLLa LavaLLTFa44 25. S.8 U.* 25 19.19 8 FaulLY massaktpat 'J g455'88r5 WImFs 76 IS.3 9.. 2S. 13.9% "O FantLT n ,teFLt.gpal OLivEL.a SP. 25. 9.5 0.. 25. 19.39 FAMILT PTweegnELLgpat 03957qela SP. 76 15.3 0.. 2%. 13.9%
toisennsLLa SP. Th. 35.3 0.* St. 22.78 Fa4tLT BI55014108F utS50sta SP. 21. S.I 0.. 25 II.19 FamILT T49pIDaC eTpCnCFTwapa Pt.ICOAa 75. S.8 0.. 25 11.39 FAMILT fnLva1FLLgnaE CTI. led *0M"LLs etauft St. 10.2 e.. St. 22.10 De no.e my0! Pea =Cuta Uhl0 SP. 2,5 . S.I 0.. 21. II.39 PM I Lt'* A87pe0F904 57.066 31.481 21.6033 4.72n? CLa5b Ceuttacoa SumCLa55 CO** P"D a 080Ee CaLamqina FaetLT aca>T330ar acamTla Tog 5a 138 141.7 4.. 637 273.98 0* tea CTCLupnIDa Usin %Pp. 25 S.1 c.. 25. 31.39 544CLa5% OSTwaCona untn. Syp. 968 393.$ 25.. %3%. 399.56
~~$URChass estarnsfaara OR DF.D~~
T S I n a rp. a o :n. se. 2$. S.8 a.. 25 St.39 res -3 nenr= T a ra n nare . Dc lq @0 g g Suanenta ni i; cP-naa .
r , [ y;/d 4 g;b,;1q,a:j , a.- unl n=to, se. 802. 2o.4 in. s3.20 IJ %g , , ! (
.sn an. n. . on.o. n.e,y 3. a - u t n=in. SP. sess. ..v S isn%. 9 4.76 m ,
s a Table B-1 (Cont.) CDhat t.L *t it al.F 6 kf>DV 1919 ut enaf e sse rnuats ouspfFu pa51L . COMTwot DOTTng Cour O Lf8pIDA Pom e.P rnw pue s t i n* ovraaLL (numumIIT Stauffukt afuoy at CarstaL wIV9m PDwoe Pl. ant .
........sursera nr 3 men g y 3 e.o a t.s........ ....... pep sop a w n. 5:16. w . .. . . . ....wrt ur3Luv.... .... Day urlGut.....
h span mange sfu noV f nf at. eram/82 TOTAL stante7 Tason ramIL1 matt.laPSEHDIDa0 maLLlaP5turJ5 SP. St. 10.2 c.. 2%. 33.95 nonsa psePona ra*ILT 84Tn*IDIDaE
*I=lP. SP. 155 Sh.9 n.. 229 100.25 Fae3Lv SacrjuaLLamIDag H4tO. MP. 25 5.8 0.. 7%. II.19 ra4tLV IDHTf.f DaE 4:450 58 Th. 15.1 0.. 2%. 11.95 raulLT SPHar8DeaftDar H4!9 SP. J5%. 50.9 0.. 778 10n.25 Ou D* # apPH3Pona ,4 ra*ILT asPaLISCIDaE 44I0 Sep. 306 63.3 0.. 295, 380.48 3
Ds rangor anPastocnIDat g uplD. %PP. 255. 50.9 0.. 132 50.93 s- FastLT apPITHOIDAE C3 "htD. SPP, 2249 448.2 c.. Inal. 703.54 ran3LT anminst Sng 49 ashtD. SPP. 3499 697.7 St.* B451 raaILY p at t i n aF. umID. SPP. 600 137.5 0.. 433. 184.56 FamILT CaPaLLLtDar 30,62 HgIO. SPP. 306. 63.3 25.. 177 ramILY CnanP43tDat 4930 SpP. 3745. 657.0 0.. 2215. 960.03 rau1Lt l.F UCis1 Hn l D aE
*J 4410 SP. St. 10.7 0.. St. 22.7e raatty L3batsonGIIDAE UhtD. SP. 107. 20.4 U.= 76 31.20 (7ZZq rasILT *tt.ITIDat ,
U410. KP. lAR4 37e.9 25.. 1444 449.94 raetLY othlCEwoTIDar. UNID. SP. 75. 5.1 0.= 25 11.3 rantLT PuasoCDPMabinar uggD. SP. 76 35.3 n.. 25 13.93 raagLt pa g f uCLu titin g tn HMID SP. 107. 20.4 n.= 16 33.70 ' c;1[2) QROLD e6CaPuna Q FaulLI aLPerlDaF aLPw.us snp=an=3 25. 5.3 0.. 25 II.39 L I rantLY MIPPHLufloar E ____2 Ts'n> Ideasist 107 J' 0. 4 P.. 397. 45.55 L- , 9a*lLT P a f.Pr t h a t PaQlwy% Frp. 724 4%.e n.. $%). 63.41 - C( y raelLY P l a *4 f d'.* l u a t ci;;3 J PIgelsa SP, 177 25.5 n.. St. l#.01 J
; ra418.T PO*Ctt.ladinaf -
u Pt'TunLISTurs sweaTug 377. 45.5 d.. 377 56.94 FastLv s a=THIssar enerPanortys nappr$gy% Th. 15.3 c.. 74 34.14 .
Table B-1 (Cont.)
~
Cf'*I.I I.L a8 TC aLF a re int 1979 pgpoof yng roupTM gesseT* p GaSte = (quienl, UWE#aLL 60TfD* CD*8 PLDelta PQat# CDePAtaTIOu CispotinITT ST8DCTHut. STUOT AT C9fstaL RIVER Ponte Pham? .
=======.pu= Pre OF IPDIVIDuaLs======== ======.PER sciss et; a p TD 4 ====== ====uFT WFIChf==*= **==Def DEIGHT==***
~~N mLaw pa*C' STu UET TOTab~~
Fab /82 70 fat urs>tm2 Tax 0*
mf09amePE TLlama 25. 5.1 0.= 25 11.39 genpa40PE SP. 802. 20.4 4.= St. 29.J1 alt 490Pa*08EUS NaeplSII 7%. 5.0 4.= 29 II.39 Umlu. SP. 4p4 86.4 0.= ITA. 88.94 Sis #08 0t
mafagfla Ca8IOLa, gne,a 2g, 5.1 e- 25 II.39 voto. SP. 25. 5.8 0.= 25. 11.39 15.152 3.030 15.4775 3.0955 PmILU4 Eculeooreeafa pl.1 u.= 255. IOW.9)
U4IO. SP. 306. PMILue C"Genata 190.404 30.0 50 98.6998 18.3300 Ct. ass ASCIDlaCta 102, 47 a4
~~M 4*ID. SP. 255. SU.9 0.=~~
~~I te I~~
~~V w~~
l b 4 o
i j Table B-1 (Cont.) Chh4Ft.L e6'TCatr g snny 8979 saSin = crihtmOL WFPese t t enu Fflg4TN Ositpfra 30TTps CDet k l.fpdipe Puwf'M filP Pa t# 4 T it'N OVERALL j Comas 3MITI ATpHCTURF. STHet 87 rkTSTaf. utvre Psiota Pham? ..
~~========muepER Dr I pp t v e ntsal.8========~~
, =======l6R 501saeK MFTEp====== ====dF.T WE ICM T==== **==DAT WEIGNT===== l TeXO4 N ht. S N WANGE STO DLf TOTAL NFAN/p2 TOTAL # FAN /m2 1 TUTAL 1800), 34000.5 6348.= 20066 S558.09 1445.225 209.045 1945.6532 209.3306 1 f a 1 i i N 4
~~,8 I~~
~~PJ t_D i C3~~
~~=J g ,~~
w> I - A9 nS C e 59 . cc w w w
Table B-1 (Cont.) C3%h4LL ttTCalf & LDOT 1979 Ra$le = plSfhafGL utPnNT rue FnHRTH OUapTER MHTTHm CDAF D'ListIDa POe f M CisDP9waTInt OVEtaLL rne m'es t T f STRUCTunt STttof af CatSfar,klVER Pfl Em PLa47
========therF8 nr tuniggnHat.A======== =======P90 squ a n t: m#TtP ===== ====wFT gr.IC#f==== ====DAT uttCMT=====
Tsang 6 MFab WawCD STU DET TOTAL *pau/m2 TOTab ofah/d2 PHILUs pn4IFEsa 14.388 2.044 4.4626 0.4668 Whip. SP. St. 7.3 0.= SI. 19.2% PMILum PLATTMFLalhTN($ U. 0.0 0= 0 e.c0 UtIO. sr. St. 7.3 n= St. IV.25 PMTLtin a%C4tLalmTNf3 0.025 0.004 0.0802 0.0085 U r:IH. SP. 327 30.2 9.= St. 19.25 PMILUM 6E*EAffata 0. 0.0 0.= 0 0.00 UNIO. SP. 255, 36.4 0.= 229. a5.55 pg PMILile a6hELIOa $9.409 8.487 17.9043 2.5570 l Class OLicoCMaETA co " min. SP. 2978 413,8 25.= 1A9 247.51 3 CLASS PnLTCMaFTa
** FastLY a p a a r s. Lins t LJ Sch!Stuatw34GHS alfDOLPHI Ta. 10.9 a.= St. 20.04 FaaILY CaPITELI.IDaF CaptTF.LLa CAPITATA B)?b. 196.4 4.= 709 279.62 NETFoomaSTUS FILIFnnalS 25 I.e 0.= 25, 9.62 *FDIOsaSTJS CaLIFnsutENSIS 4883 607.5 0.= 3920 330A.39 SCf Ph0FenCT05 PLa TTPmDCTUS 29 3.6 0.= 25, 9.42 HalD. SP. 102, 34.6 0.= 16 20.u?
F e e l f.y CgnaafutIDat TNaMTE SP. la26, 203.7 0.= 964 340.22 Fam!LT fHhlCIDar wapPat%a $4=Gettgra St. 7.3 d.= %I. 89.25 fan 3LY f.L rte e l DaE CLTCtwa a t.=tra44 204* 29.3 0.= 102. 49.70 FantLT MFSInhipat CfpTgs eht.vspaLPa 351, 28.A n.. 14 27.22 HmID. AP. 16 30.9 a.- 16 20.A7 F a m il.T L'la p w ! 4F#F10ar LHendI98dl5 SP. 76 30.9 0.= 2%. 33.68 Family w a r.(Lan g r a t. escrLo a P6 TTiwsgEat 993. 148.9 0.= 4Sa. 156.e4 Fan 3LT m a s.p a a l p a t ' a s t.pTp5'LLa murH5a 96u. 33s.4 d.= 417 237.91 CLV*t*>LL4 TopouaTa 25, 3.6 e.- 2%. 9.62 U%I4 SP. ?>, Ib.9 0.= %I. 20.04 Fae]LW wDpainaE c/pa7a=+ pets gestraplLIS 76 30.9 0= %I. 20.04 t r e a Tr 46 *
~~3 5 ?.P. 25, 3.* 0.. 2%. 9.62 e' g 232p.9 20s.= Oth*. 22S6.07 jh/f}~~
~~Las n .. .. l s cHg.v e s t 16sah.~~
~~e >> l s shr( l=6 a 2%. 3.4 4.= 2%. 9.62 't Jfi i~~
~~ynfu. Ap. I Fu. 25.5 0.= St. 20.19 f I /d F a 4 f l.T 4*34PHinar~~
~~, DInDaTwa CHPdta 25. ).6 0 25 9.62 k~~
t Table B-1 (Cont .) COHWFbl. **'TC al F % supi 1979 HFPDhi 90P FnippTM 00asT6R pastu = DISCuaer.F SLONlba Putt:p CokPopaTten ovEm al.L 807T04 (087 COmgUNITY STAHCTuut stunt al CWYStab >lvru PonEn PLauf
= = === === tu m pt p f*F laptvl4 Hat.%======== =======PFk 80itter MFTP.R====== ====uff WFfCMT==== ==== pal wCICMT=====
N Prag ParGF STD IF.V Ynfab PLAN /u2 total. Mfah/82 TaInu OuUPMIS hFryLUS4 564 80.0 0.= $60 293.14 Fa48LV nN P I'll l D a E Hapl.05CnLOPLOS PopuSTHA SP). 14.6 4.= t. 38.Su mainFeVIS %P. 's). 25.0 0.= 153. 57.7S s(nLDPLn5 anFaa JSS. 3e.4 0.= St. 20.04 Umip. MP. 25, 3.6 0.= 2S. 9.62 FaulLv P an a0mI D a t:
, setC10La PHILRimat 21161. 3023.0 1474.= ellh. 1939.13 aw1Clura TaVLup! 2725, 359.2 79.= #93 314.20 au1ClpEa SP. 53S. 76.4 25.= IS). 50.9)
PapanninF5 S*. 2%%. 36.4 0.= $53 54.73 UhlD. SP. 76 30.4 0.= St. 20.04 Fan g f.T PHYLLOOnCghat P9 uptp. SP. 25 3.6 0.= 25 9.62 0 FamlLT SamLLLIDaF 08 CHowF. pugERI 25 3.6 0.= 75 9.62 8 FaPetCla SP. 6il. 87.3 0.= 407 155.49
#' FantLT samf LI, api tuat' #' SaPELsaula vulca#IS 25 3.6 0.= 25 9.62 FaulLT simpur.gnaC UNIO. SP. 25 3.6 0.= 2%. 9.62 FaulLT SPtnutpat PARAPRinhuSPin PINNAT8 910, 2S.S 0.* 102. 36.nl '1CJJ Pe S poka ufP5TERS 5089, 14S.S 25.= 662 229.99 Pu n.*40%Plfa HF TFRUR AaNCHI A 121 15.2 0= St. 24.22
(;C}1{D) 2 Scal,FLf Pls b ayamaT A 931 135.0 0.= 453. 377.30 51 h Fmt.0%PI9 HF"',DICTI $273. 151.9 0.= 1944 305.47 y:{bh) e l Fam1LT SVi l l n48 hjkC3 Psamla CLAVATa 25 J.6 p.= 25, 9.62 ODomT057LII$ %p. 25 3.6 0.= 25. 9.62 Spna6605sLLIA SP. 74 30.9 0.= Th. 28.47 SYLLls so. 3894 SSh.6 n.= 38Ss. 1814.46 9.62 i ogin. SP. 25 3.6 4.= 2S. CJ FAMIL1 TFeePFf,LIDat 57wskLosn=a MaPf4amar 25 3.6 a.- 25 9.62
'- - " UhlO. $P. 102. 34.6 n.= 76 20.h? ~ =0 C PNTLue 80s,LUSC8 '- - " Cl a ss amputasuma 4.504 0.695 3.2580 0.4645 Family arag1porHITnNIDar D[Er( scantroCHIvora PvC=sta 16 10.9 4= 76 28.81 2.674 0.382 2.03?? 0.2980 Fam!L1 I SCM* nrp lin a i n st =
I .%C n hor M I T na P a P I LI.0 %U S 433 68.0 0.= 413 Inl.62 16.954 10.999 69.0931 9.9041 y Cf.a ss B I v a t,v l a 25 9.62 La6WIC&WDIH9 an87048 25 3.6 0.= - Faul%T f.VH%%3that LVO4Sla uvablea St. 7.3 n.= St. 19.2% FantLv % rapt. gnat = C"mINGla %F. 25 3.6 0.= 75. 9.e2 FadlLT 7 8 9.f.I s s u as. TILLiga %#. St. 7.3 u= 24 12.43
=
Table B-1 (Co nt .) (u"4tLL mpTCaLD L IDOV 8979 mFPvWT enn Fouptp OUamT6p eastm = ng5Cuapct FLownpa Postp CourquaTInM OVERALL ROTTne Coar CUPauMITY 5 tat'CTunt 5T00 47 CarsTab pfvfp powEm PLauf .
========huePEk nF IgDtVfDH4LS======== =======ete squaer mattp====== ====wrf yEICHT==== ====DMT wtICNT=====
a p p. 4 W p a mG6; STin DEv fniaL mFtu/m2 Tnfab mF44/m2 Taaon F4 WILT VFwERID4E CMIO%E CahCFLt.4TA 25. l.6 a.= 15 9.62 . CLa55 c.shTenP006 62.134 A.816 98.6548 7.3786 F a
31.y artsnelglbar aCTFOClea Cagaq,1CULaTa 3n2. 54.6 0.= 127 49.70 Fangby apLLtpar

putLa STulaTa 127 18.2 a.= 16 20.33 Fam!LV CAFCIDag
! CaFrH* SP. $#65, 280.4 0.= ISA4 707.69 FaulLt Cat PipHLinar CuEPIDULa et.aea 255, 36.4 c.= 255 96.25 FaPILY CEnITwigDaE C E R I T"III" "95C a mism 433. 68.9 0.= 433. 163.62 p4 utTsua vaatum St. 1.3 0= 25. 12.43 I FapILY CnLu u n t LI,I D a E Da altatt.l.a Ignata 25. 3.6 4.= 25. 9.62 i FagILY mapGIm>LLIDaE
** CwasnLima nv48.jFOpplS 76 30.9 0= 76 24.87 LA mapCIsrLLs LavaLLF.Faga 102, 14.6 n.= 102. 39.50 FaulLY maisapspar naS5angu5 vgeta 1h. 30
0.= 51. 20.04 URDFR WUDlh88tChia uh30 SP. 16 30.9 0.= 16, 20.47 PMILU4 apTNp0Pona 16.003 2.482 4.4019 0.6297 CLa%A Ca usT a( E 4 SUNCLn55 ropFPnna ORDre caLs=< tina FaulLT arant33Dat aCadTla Tn45a 25. 3.6 0.= 25 9.62 Faeltf Ol a Pf an g n a F.
~~P5puenussPTD*HS Cuannatus 25= 3.6 0.= 15 9.62 Fam1Lt TF=0minaE~~
TLar;pa Tup >Imata 75 3.6 c= 2%. 9.62 DenEn pampacrtCnina U410 APP. 127 th.2 n.= 427 (e.32 SUBCLASS n$tasCnDa 132.79 UWgn. $pp. 948, lau.2 n.= 240 SUSCLASS *ab4CD%TMACa ,
~~OWDEa Cumacra 16 10.9 8.= 58 20.n4 h Op6FW TaMagnaCFA CalD. SP.~~
~~] j ~h~l0 [g 3~~
~~l l f3 ij j 5Hkok Dt~~
~~Dise=0PMDBA uu F.o.0.s ,tn...,,n sp. a n. 0,,.n. a ae0 au.e 0.= 155 95.12 ,~~
3[ y [ m ua10 Ap. 127 Su.2 n.- St. 24.22 09CfR laDPO94 8 UNin. %P. 2%. 3.6 0.= 25. 9.62 . FaulLy a m Tp'sp l oa r UNIO. SP. 102, 94.6 0 St. 24.85
e 4 *
~~) I I I~~
i 0 0M 9E e8 9% **
> not J GW en p k e3 &4 O es a e E to O e& ME o = lee ** O C> W C 3 1 > > ma a qe 4 2 D> 0
C eO C b 9> O 9 e e O 9 9 ee 9E S% W
~~>E C~~
Ze C IJ =>

es E o W
~~3 b4 3= #~~
#> N $= 0 0 0 W 9> e 4 0 O m3 E D 6 9 0k > m e n% 9 9e > m 9 N en a >
3 9 9O W G @ d fe @ G W G @@WW O C 0 0 e o e o e e o e * *

e *

l
~~& 8 e3 9>~~
e N se me e e e den n O ee ma O 9 d 9 4 se M se M M l. z eee a e. w ez
> ea 3* = V. en as C3 s* * * *
~~e o e e o e e o e o~~
~~= = ah 4 = M e a e w e == ree4 a=~~
~~2 >J 2 P* f%~~
~~N > M N N d MNN> #~~
h ee Eo - P se P e ee == a lei en of O4 >eC S 1 es em O m-hCa3 3Ce a 5 0 e e a 3 e e a eet 9 4 CW 2r3 e e e o e e e e o e o e o e e I = 0 0 C C O C O O O OCCC O up k &
>&3e ime e aC* C em a ik a n= s b IO S S e3 a & = ini e J > &s e == ae e e @ g m e aem? p e e W3 F e2 e o o e o e o e e o e o e M Q = $e e e e set m set > > c m m F* O O N es 4 4 8e se N ro 8st O es se se 3 EE 6 E se f%
~~W Q3 8 J oe 0 he U S~~
& 9 x e o e o e o e e o e e e e o e a 9* 6 8% @ fe W* F @ me se e @ # an e d W $ 3 O O f% M M N e c > reme> pe se M fue s% e > en en as as R
3 W W C U e 3 n I M l k w \ e al S O e & lel w on O e
^
e = = es c la' O C 0 lap do? E b o e e se les == a et e eme eVa e e g e C fee e a= D C C&E 6e eI ee oO eT e 1# == & > (L* me O .3 WI &F. e C o w
~~==a :eQ>~~
~~ina w = s - s set.=- 1= O ces a a ,o & ok ** *=awOer&=~~
= ak c = a e oaea a dL e r e - q n Q b*
~~a C M ik db # 3 #. k W a er J # J F. O J GP Eed A C7W O == c = c = w ass ==meFb a~~
'o V. i l l ') ; h V e i p, E
~~ce e r es ee eE eu e J eE o se & a & *= ee & e & e c sk C C C C O = E se a C = O e rC l j,r 'g~~
~~.,.;f g~~
~~T' l m~~
] .I l i O ee a ** se = se es O == u. V F &CF= ==== ,j
( - jr3 I I g de > Se>N DENTha>Fh2C>e>=>=a el 2F aI Q
** S 00 el 3 e4 3 e4 3 J 3 .2 L sa = m3 = ma ik m3 & 2 ue F & 1* %# 3 t 0 = = = = = = = = = = W g3 & a aW W 5 a a E 13 E E s sa ke as e e e e ae e e S b Cb h b im Em he Om b he E # ac a a a M =>
~~v. >~~
C O c .sa y eO se e se E 36 > & l l l I-B-46
~~. . . _ . ~. _ .~~
~~r f~~
~~.t i~~
i i Table B (Cont.) i Coahe t-L #5.trae r 6 rooy 3919 FftgeTS OuteT8 8 easte . PIKatoGE .etenef Fne F L'em ik A retFe rfwens af f em OWEsaLL mu7708 Cath E CDeaustTT 57ebC19et STdDt af retStaL utVre Ponte Pt4mf .
........svette or 1ergstavats... ... .......pte sosser e, fee .... .eff DEIGeT**** . 907 *EfGet..*.=
a me as eagCE STD D*T -TOTAL etsete3 -7098L egampet , Tetos . Tnfat 74833. 19685.8 8149.. 19e73. jete.g3 331.900 33.eg1 155.031$ 33.9768 I I
~
t H i i tW i k N f I j. i Tc R
~~/r @M$o'5lh p~~
6m..qpapu hv w b . UJ , f a } h 4 t
~~, e a~~
i e 6 w e
Table B-2. Basic statistics for each taxon and wet and dry weights for each group from venturi suction samples of 1979. COmhELL mETCALF & EnDT 8919 sAstm = CnuYanL utrom? Foo Flas? DU4pTER VENTURI FLOSIDA PomfR CosP084 TION OVEpaLL CommV41TT StauCTUpL STUDT AT CnTSTAL RITER POmER PLANT
***=====mumpts OF In0tTIDUAL&===**=== ==*====PER Souset 8FTLR===*** ==== MET WEICmT==== ===*D87 WEICMT===**
TAIDu a mL*N p a m Gt STO DET TOTAL ptAN#p2 TOTAL mEampm2 PNTLUM P0mIFEma 58.022 19.364 22.7738 4.5945 Umt0. SP. 4 0.0 9.= 4 8.19 PMTLUM PL&TTMELuleTMES 9.081 0.911 0.9837 9.9927 UmID. SP. S. l.9 0.= 3 8.22 P4TLUM mEmEnftmEA 9.403 9.908 0.9454 0.0833 UmtD. SP. 82. 2.4 9.= 1 3.05 PMILU4 SIPHmCULA 1.222 0.244 0.2844 0.0429 UNIO. SP. 23 4.4 0.= 28 8.18 p, PMTLUm at4ELIO& 9.184 8.943 8.4494 S.3333 g CLASS POLTCMaETA ce FaulLT amanELLIDat saaeELLA talCOLOn 9 l.g 0.= 4 3.79 c- FamILT cap 8TELLI0at CD SCTPMOPROCTuS PLATTPROCTUS 2. 0.4 9.= 2. 0.89 UNID. SP. 3. 0.2 0.= 1. 0.45 FAmILT EUMICIDaE LTSIntCE mimETTA 2 0.4 9.* 8. S.SS manPHT54 SamGUINEA Bl. 6.2 9.* 24 38.06
'-~y}3) armatomERIS UntC08EIS 8. 0.2 0.= 1 0.45 FamILT FLauELLICEAIDAE (Eq}}}) PinonIS Leuca 3 0.2 0.= 1 S.45 ~-
FadlLT GLTCERID4E ([kE fI GLTCENA aus.mic;LA 3 0.6 8.= 1 0.55 C; ' 23- FAMILT ME5lHhIDaE g- GTPTIS geEVIPaLPA 1. 0.2 0.* 8. 0.45 F4 MILT 84GtLumlDat macELoma PETTI90 gest al. 0.2 9.= 1. 0.45 FamILT maLuangnar h- __-- att0TMELLa =4COSA 32, 2.4 0.= II. 4.83 hDCJ) FAMILT mretloat
~~LALO 4,. , CULTE.i 1. 0.2 ... i. 0.4.~~
2.4 12 5.37 t;Cr*), bi~r~- ms. meg 5 FaLS4 me ar.1 % SuCCamE4 32 10 2.0 0.* 8.* 7 2.92 [i] _a PtaffsfPFIS DueFRILII 1 U.2 0.= 8. 0.45 . . c;_, j UmtD. SP. 4 0.3 0.= 3 1.30 = y% FAMILT OmuPM80&F 94WPMIS 48R0005A 15, 3.E' O.= 10 4.47 - [3i r-___d3 Fan 3LT Omalesgoat MarLO!/hLDPLUS MORUSTUS 4 l.2 9.= 3 l.30 b m a i m. m. i5 s. .. 4.2 a.= s. 2.if - SCr*LHPLDS ada84 S. 1.0 0.= 3 1.24 FAmILT Pamaumlunt amICfbts Ta:Lne: 'l. 0.2 0.= l. O.45 - Fastby pr.CTi man 3 3 n4E PECTamanga cautnit 2 0.4 0.= 2 0.99
Table B-2 (Co nt .) Cn=4LLL affCALF 6 EDnf 3919 OAsle = C04Tn00 nr.pnet e na Flest ovanTLD VLaTURI FLudIDA PnufR CUnposATInn nu t s a s.L C0develTT StauCTunt STUDT AT CMTSTAL DITLA pomes PLauf
========munsta UF ImDIVIDuaL5=====a== ======= pre souapE apita====== ====mLT WEICMT==== ****DA T kE ICMT=====
TAIOm r mLAm #44Ge STD DLW TOTAL *panip2 TOTAL DAA##m2 FAMILY PHYLL 3 DOC 104L LTE0er usTgm0PoDA 1. 0.2 0.= l. 4.4S FaulLt POLim0luaE gApm0THOE ACULEATA S. 1.0 0.= S. 2.24 LEPIDamLTata CommENSablS 36. 3.2 0= 9 4.e9 LEPIDom0TUS SP. 3. 0.6 0.= 3 l.34 FamILT SABELLANIIDAE SAGELLARIA vuLGANIS 2. 0.4 0.= 2. 0.09 FAMILT SLFPULIDAE U4tD. $P. 3. 0.6 0.= 2. 0.09 FApILT SPIONIDAE PkIO405P40 METE 800aANCMIA 2. 0.4 0.= 1. 0.SS FAMILY STLLIDAE STLLIS SP. St. 3.6 0.= IS. 6.50 pg FAMILT TEalmtLLIDAC g LTSILLA ALGA IS. 3.0 0.= IS. 6.fi gg PISTA CalSTATA l. 0.2 0.= 1 0.45 g PI%TA Pat,mATA 3. 0.6 0.= 2. 0.09 S* P!btA SP. 8. 0.2 9.= 0. 0.45 43 STkEuLO50mA ManTpamAR 22 4.4 0.= le. S.90 unin. SP. 2. 0.A 0* , 2 0.pt L*4kF& AOLLUSCA CLJ ; 6 ARPMimLupA 1.125 0.215 0.5892 0.8030
^AmILT ACA=TM6 CHIT 0mIDAE ACA4THnCmIfowA PTG4AEA T. 1.4 0.= 5. 2.19 FAMILT 15CMm0CHITu4IDat ISCuw0CMIT04 PAPILLOSUS 66. 13.2 0.= 34 30.09 CLASS SIvaLVIA ft.56s 14.392 St.TTSI 80.3550 Latv!CARDIUm m0RT043 10 2.0 0.= S. 2.00 T8ACMICapDaum supICATum 8 0.2 0.= 1. 0.45 FAmILT CAPDiflDAL CARDITA*F84 fLONIOA44 l'S . 3.0 a.= le. 4.24 FAMILY CoahuLIDat CopeJLa ComTpACTA 1. 0.2 0.= 1. 0.45 FAMILT LTomSII0ar LTomSIA HTal.ImA 3. 0.2 0.= 1. 0.45 FAMILT mTTILfbat l
~~15CHAulum apCuevue 2 0.4 0.= 1. 0.55 '~~
=95Cucu5 LaTFmALIS 2 0.4 0= 2 0.09 FAmILt =UCULtnae . I m a NHCULa ewontaa 9 1.0 0.= 9 4.02 f[LC. -l Fan 3LT 05tattoat U d jit Ig a; er
[ 1 CpA5505 Tera alpGINICA S2. 30.4 0.= S2 23.26 (- U '"* ' USTmEA tu es 5TWIS II. 2.2 0.= 6 3.03 1 FAmILT 5ta t e.'3 8s a g - SF= ELE P4*FICUA 3 0.6 U.= 3. 3.14 semELE Piampuwa5CEm3 .2 0.4 6.= 2 0.09
=
~~F A m it.T TELLINIbat TfLt,lma Sr. 3. c.2 0 8 0.45 e~~
~~*+-memmewe+m. emme ce w ee ee eee We * *~~
e e

Wee = * =
_ _ _ _ _ _ _ __________-________m__
e 5 0 0M SE OE 9% e N
& em wh 9E e e e em J to e O O = a as 3W e a ea Ua e
~~3 ene se > e O> W O 3~~
> meop e & Se > **
as O t- M es w eD en M 8 to e em g e a e > es an ce s e e fe 6 W I% O >
$= R W' M E as ** >
~~u se 'e e~~
'ea m O e W **
3 De WJ Be 9 9 en e n"* to eO fe e 3 0 to e
~~e 9 D 84~~
~~.3 e e=~~
6 ame 9 9 e e art e 9 eOe e# ePt e r= em a en e Wt em e e e C se I 3 9 es we e e mmM me e e e e e e O e e O e m 9 @ l O $ 0 * *
e e* * *

e o e e o e e e e a e e e l & 9 9C OO O m == en fe es M O O se O es O sut O O O O e .e. em 9 9 e= 9 M es l E ese ins ez l as 9 el i 2= ef! >
~~t > .3 . e o e o e e~~
e. og so o e e e e e o e e e e o e e o C .C a as s ==== a= a e. e se O se e se p se ao se g on e C 0= J 3 e e ce em tas ee OA a> == a a e O wt >eU 5 G. a= == = a en 4& OCe t 8 0 0 0 4 8 5 0 0 8 8 9 0 0 0 8 0 0 0 0 9 9 J w" O w y c3 e e e e e e e e e e o e e e o e e e e o e e e e W em OO O O OO3 3 == O O O O O O O O O O O O 3 O u t= Gm a
>S&4 4 as m C me C em &&B e= e mOs ae J s 45 3 ins e J e= se re M e M eMM eO M fe d e e M e fe fu e e ce M O el e ef) E 4 3 e e e e o e e e e a e o e e e o e e o e e e e a O =$e OO O M O a= se t O O *st O se O me O O O O M ee os E en eb gea N O d'm e me 3 5S 6 5 W 03 e .3 es 0 wu 8 & 8 a e e o e e e o e e e e e o e e o en o e o e e e em e em se M em M e en m eft se en O pe en se O .e. se go M .e g y e $ 3 es an e e en se t= ==
~~I E W e De as e W W es est afg J == =~~
==O ea WW & tal W e se es e k e4 De eft 2 3 al se e 3 esp a y as 3 er t= S W e5 O tap 5 4 W O em e se Gn; U O O b g e2 tal e taf J e fe# F e C w == .3 O u en as se e z == = w JC e saw .3 u aw e= C as eJu O o ma = a e a u == eS == ** 3 u e O 3 eft .3 3 J .ee & isJ ase ==e & es e. e et sa ; en e == J dJ e he se e J w e Jem1 3 Jeftas J e e e= 3 es e 3 ee e a E e a u os c Ove me a .a W e int oeQ 4 3 e a & = w a W ee J = w c O z e x C = a e en e : ==>OO me CO s e= . m & .a =
~~a3 wu o o~~
~~== a e=~~
e e ex ee e a N a e .3 e s se e =* e 4 4 to S9 8 U = a em J U F e e9 U ef as .% A to 3 4 euO e In eW e C .3 % > 3 3 & V taf W e6 C == e J aw tb J e3 J == 3 % .3 4 b e J .J G e es e m == er 3 U e U a e a &
~~e.f &4 ice & = 1 = Qw u.t~~
%# 5 ECF JN e3mh 1 en e as tau C' W R .3 et e e et 3 Q en C C ed I er' & & er & eP 3 a4 J tme W ist (L e a; CD J tPI led E O3 C3 33 5.is asEem ice 4 e 3 3 J at a e == &V3 e3J3 =E O "J & e= a 3 C C >reO3 a a e u se ** == u to e= W C w me E se a e r e a a c as - E a e e= ee e a me e ett *2e ee ae
X Caa se .a a sw & == en U U se a te y e a ng O a oo O C& c O N *=
E
~~==*t= W J = 4sd = ea e t=~~
el a est O ws wt J z wt a > *e e 3 == wt == == s == 3 e == g > T e e k e > 3 p e 3 3 > W e' W C h e > e > E w e > T WS We B 2 k k' E m > E P E e > F P FW E O e3 O 9= au 4 E J = O J V W U J U mW J t.' J w J W *33JrJ& W a eR .3 E WS 3 O= 33J3 J 3 4 3 .3 % N U = Um m m = m m a m 4WHm o a = m m a a W E E W W E E E 5 E E eW as a eO 83 5 89 E S g 0 se as at e as as e er. e e e as ,,.3 as .J eg tel r a: as e We e m N 33 a 6 ew w k 6 6 w w w m w 5evw uo O3 Cw w cw w w 3 eft 3 aft t a3 a en a a
~~.O m e=~~
48 8 c e Je3 3C O O O gg ee ea a= .3 e et ge
~~er e u zu~~
~~- S> Ge &~~
OO } D D CI Dlfl} i Imamso oo3 - 1 M J N,J @ d b . 4 6 e I
Table B-2 (Cont.) 1919 CummELL mtTCALF 6 EDDI FIRST QuapTFR atroaf pos 04514
Cu=Ta0L GVFhELL VENTH88 FLDA10A P9mPR COWPOW ATIt 08'MM441TT STpbtfukF STues AT CptST AL e'4 lvEm Pnuen Plan?
~~========mumPES Op 16PIvlhDAL5======== ====.== Pip squaNE e6TEh====== ====stT utlGMT==== ====Def WEIGHT **===~~
TOTAL DEAN /m2 TnTAL stan/p2 m DEth m44CE STD Dtv TAE04 Fam!LT C0a0PMlloAE U410. SPP. 2. 0.4 0.= 2 0.89 FAMILt WELiflDAE 2. 0.89 Unto. SP. 2. 0.4 0.= ORDER hECAPODA Fau!LT ALPMEIDAE ALPMEUS AWMILLATUS 10 2.0 0= S. 2.f4 ALPME45 NETERDCMAELIS 6 1.2 0.= 4 1.79 ALPMLUS mownaamt 88. 2.2 0.= 10 4.38 e ALPMEUS SP. 4 0.g 0.= I. 3 30 FamlLT CALLIAg45$30AE UPOGEn!A AFFlut5 32, 2.4 0= T. 3.36 FadlLT MIPPOLITIDAE 22 9.47 NIPPOLTTF PLFURACANTMA 26 S.2 0.= P4 TMon FLonIDAgus 30 2.0 0.= f. 3.09 I FAu!LY 4AJIDAE 2. 08 ListNIA Ouelt 3 0.6 0.= 0.89 8 FAMILv PAGUWIDAC 2.65 LA PAGuens SPP. 17 3.4 0.= 7.
"" FAmlLT PALAEnf6MIDAE PALatm04 FL0stnamus 3. 0.2 0.= 1. 0.45 7 8.4 U.* 6, 2.65 PALAtm0NETL5 lettesEnlUS 2. 0.18 PE4tCt.I"Edl5 AptelCAgUS 5 l.0 0.=
PL9tCLimENES LONGICAUDATUS IG. 3.6 0= 8 3.65 . FAMILT PLh&EIDAE 3. I.34 pruAFuS punasaug 3. 0.6 0.= FamILt Pimm 0THERIDAE 8. 0.4S Pl448A4 SP. 8. 0.2 0.= FAMILT PHPCELLA4!DAE 2. 0.89 Pt.TantisTwES ApeATUS 2. 0.4 0.= FAMILY PmOCL551DAE 1.34 A p p l DF. t TLM himmETRICuS 3. 0.6 0.= I. FA4fLT sayTntCAE EUstpan0FFUb OLPaEssus 90. 19.6 0.* 49 26.39 6 2.60 r c5 6 3.2 0.= tuRYPA%QPEuS SP.
~~1. 0.4% } hk MEIAPah0PCU$ SP.~~
WF.OP A MHPE PACEAWOI 3. S. 0.2 I.6 0.= 0.= 6 2.Al Q h > pfa j 5.68 p Lfl ~' mE0 paw 0PE YtaamA 25. S.0 1.= 14
~~/qu y, ,~~
3.6 0.= 9 4.93 nrnPannPE SP. le. 3 1.10 PANAPCUS UCCIDENTALIS 4 0.0 0.= , alTManPagbPEUs p4Raggli ). 0.6 0.= 5. 1.34 = Ugtn. SP. Bl. 6.2 c.= 20 9.0T ~ SURONDFu mATANTIA I. 0.4% UhlD. hp. 3. 0.2 0.= 11.367 2.21) 4.2197 0.0519 w PMTLUM ECMI40DewmatA uglu. SP. IS. 7.0 0.= 2). 9.14
=>
~~PHILum CMOPn&TA 153.954 30.191 24.7447 4.9489 class AstlotactA~~
~~-megemeeeeee--eee e meeeeee e-wi~~
Table B-2 (Cont.) C6==sto me.TCair & rno, 1919 nasia - Co. nob St.Pt*# T f De FIRST guaeffe VLWTUNI FLO#lDA P0mt.m fetarnpailt's outpaLL
~~ComaustTV STnUCTuat stunt af rev5 Tab htVEa ponga pLagT~~
====*==*bumsta UF imettlDUh05======== * ======= pop hettesE METER ****** =***uET WESCMT=*== **** pat DEIGht***==
T&Eng W WL&u S thCF, RTO Ot g 10T&L pfhu/m3 TOTAL stanput umID. 5#. 111. 34.2 3.= 846 62.66 1 CLASS 05fEICHTNTE5 11.196 3.439 3.4T96 0.6999 seggo. SP. p. Y,p g,= 39 T,53 . 1 tn I u PJ Ei@ Lc=> . hie) n - 1 i p- . FT M e M
~~-- a- = . _ , -~~
~~I Table B-2' (Cont.) Cone 6Lb stTral.F & Enot 1979 SaSIN~~
Cuerent erPomT tese Fin 37 Outefte VEnfuel F4 08 80a Pont e C'NDPomattne ogrestL Commiself s st>UCTUnt STtDr AF CeTST AL mlWEh Foste Plast
........sumete OF lentW30esel.S........ .......Fr.e Sorsaet st1LN...*.. == .erf eftcef.... .... set of Cat ...
1450s e stem p e eC F. STD DET TOT 40 PLSe/s) TOT &b eLeste, s t i W 8 Ut b3 N M e w
~~# 1 I~~
~~I -~~
~~e me'us eeege~~
* - - - _ _a
Table B-2 (Cont.) CumhtLL mETCal.F & LD0% $919 eastm = 015CMawce: usPO#T Fem Fl#57 Gua8TLR VENTUEl FLuptua PDwEm C08P4Na180s OVEmaLL Commumlff STnuCruar STUDT af LWastab aleth POste FLauf
========mup0Ea np Igogvl0UaLb======** =======ppy SonaDE mLfLp=====* ===*eF.T WEIGMT==== ====0af utlCMT===**
Taa0m u 8Las paaGL STD DEW TOTab eraufm2 TOTab staesn3 PMThum mEstaT3 men 0.310 0.0S3 0.05S0 0.0079 untO. $P. 6 0.9 0.= 3 1,44 PHILUM 49%FLID4 3.606 0.S21 0.6321 0.0903 Cha55 POLYCMaETA FaulLT CAPITELLIDat MLTranma57us FILIFousl5 6 0.9 0.= 3 l.28 FastLT LumIC3paE daRPMI54 na4 GUINEA 1. 0.1 0.= t. 0.30 Faalbf CLICEuloat CLfCFAA asERICasa 14 2.0 0= 4 1.63 Fan 3by GoulaDIUaC CLYCimOE SP. l. 0.8 0.= 1. 0.30 pg FamILI LusMetalDC8DaE g Lunestn*.p35 sp. S. 0.7 0.= 3. 3.11 cc FaulLT mactLDelDar a maGEt.uwa PEffisOntaC l. 0.1 0.= 1. 0.30 Ln FastLT maLoseIDar
&w asl0TmELLA m9Cnsa 8 0.8 0.= 1 0.38 emanCulna5fCMIS anLAICasa 6 0.9 0.= 5 l.06 CLT*EmLILa 7080Uafa 5. 0.8 0.= S. l.09 FaalLf N ER E IOa r.
~~LaEOkteEIS CULVERI t. l.3 0= 1. l.21~~
=LWEIS FAL5a 2. 0.3 0= 2 0.16 mEmEl5 50CCl4La 6 0.9 0.= 2 0.90 PLaTIntRE85 unufMILII 0.1 0.= 1. 0.30 ~}h[) FaulLY A4HPMIDaE 1.
~~C[___ J OBOPATan CUPata 2. 0.3 0.= 1 0.49~~
, OmHPMIS hEsuLO54 4 0.6 0.= 2. G.79 ,L FantLv om 8 8 4 8 t D a e-c;. MaPLO%CHLOPLos ROmuSTuS 3. 0.4 0.= 3 1.13 Faultf 0 Emituas ,
umEnla FUSIFoamI5 9 l.3 0.= 9 3.40 Pama0m3Dat Fa Ma IiCioEs L.f P ii.. .at i. 0.i 0.= i. 0.3. ([9.', g :0 FAMILV PECTimahlscat O' C~.3 PtCTImauga Gout 03I 3. 0.1 0.= 1. 0.3e
~~.s FaulLV S a nE LI,lD a t.~~
~~t SanELLA afCWbpTMaLPa 1. 0.8 0.= l. 0.38 r- FautL1 SP3044Dat~~
~~' = 'S g:~~
25 3.6 0.= 89. 5.06 i i PakaPRIOW0%rlO PI44aTa L__ PWIO445Plu MffreunaanCMla 2. 0.3 U.= 1 0.49 - r ramILY SILLID&6. D.I 0.= 1. 0.38 E, STLLI% %P. 1. . r d FaulLT TFhentLLinaE PISta Cu!5fafa 3. 0.8 0.= 1. 0.30 P4thum e4LLusca 0.6206 0.0001 Class elvaLvla 1.413 0.202
.e-e - mew eene me - -.w.an een.eeeneee.m4.
N@-*NeM 666
Table B-2 (Cont.) CommEI L us.TCat.e L Enut 1919 BASIm = nf5CuaaCL htPn#T FDw FIRST Outston DLOWIDA P0sta CuePnaAftbh OVERALL VEuTuRI CommunITT SfauCTuaF stunt AT CETSTAL utvEn P0uta PLauf
========munnEn OF Imptytopal.5======== ====.==PPR SunamE PEftR====== **== wit uttGMT==== ===*Def mEICMT***==
N ' tan RANCF STD DET TOTAL, PFAN/m2 TOTAL mEAh/m2 TATON FAMILY CAR 0llnaE LAEvtCaepIU4 8b8Toul 1. 0.3 0.= 1. 0.30 FA4ILT LTomSIIDat LYun51A H T a t. 3 44 9 s.3 0.= S. I.70 Fam!LY #TTILI0aF amTCDALb4 PAPTp1U4 8. U.4 0.= 1. 0.38 FAMILY 5tatttDat CH4tuGIA C04mCTATA 1 0.8 0.= 1. 0.3e SEmELE PONFICUA 2 U.) 8.- 2 0.14 FAntLT $0LEggr,ag EgSts ngenM t. 0.8 U.= t. 0.34 FA4tLY TELLI410aE TELLI4A TEtANA 2. 0.3 0.= 2. 0.T6 76.LL114 SP. 1. 0.1 0.= l. 0.3A 35.03S 2.262 12.5099 a.1996 Pd class CASTRO /bGA I pantLY Ce n t TH g t oat C8 CEaITdlu" EnuumEun t. 0.8 0= 1. 0.38 I C6.pITM!u' ad5CA80m 1 8.0 0= 1. 2.65 k# FAMILY Na55APIDAE
# NA55Aulus VIBLE 49, 1.0 0.. 19 6.06 PMTLue AwTMa0P004 2.822 0.5603 CLASS CwusfaCLA 84.056 3.92t9 i sumCL455 mataC057#ACA OMDER ISOPOOA FamILT IDOTEIDAE l
umID. SP. 7 1.0 0.= 1 l.29 FAMILT SPHatkOMAff0aE U4tD. SP. 1. 0.3 0.= l. 0.30 l 1 ORDER AMPHIPODA l FAMILY A4PFt.35CIDAE unto. SPP. ,4 U.6 0.= 2. 0.vb FAMILT A d P I T M010 a p. UNID. SPP. 3 0.4 0.= 1 0.S3 FAMILY A0agnat ugID. SPP. 3. 0.8 0.= . 0.38 FAulLT WELIfl04E 0.30 duin. SP. 3. 0.1 0.* t. ODDFW UtCADODA Fam!LT At,PHE t nat 0.95 ALPntus MFTF40s1AELIS S. 0.7 0.. 2. = ALPMLus SP. l. 0.3 0.= 1 0.3d FaulLT HIPPOLTTIDAE \ MIPPOLVTF PLequacANTHA 5 0.7 0.= 2 0.95 O FaulLT PaGHelhat
~~n. 0.v 0.= 3 8.it [fh,Q Q h97 h\\l ,}]ml J12 -~~
PAGunns Ser. 1 .C>a! di 3 *\ eq' d d F a n t s.Y P a i.a. .on i n a E Patat=n=>TF.s susta=EOsus .3. 0.4 0.= 2. c.19 G Q,sa 0.Je PaLa>=nttTES SP. 3 0.1 0.. 1. Pt.wlCLlefMIS A8LRICANUS 4 0.6 0 4 1.58 me6
r p 3 e d t t : . e en es e a en em a a ewJ es e e e e>J Ve i ese sw e. =. e es wa o e e zw m e om w e o a e e >J
~~a ge e e a~~
= op e e m eo e a e er a. a. g e
~~e e = , e en eE a ew n~~
>m p = = ,
se a. ow e a es w a wJ n = se e e sp
~~> eo op a. e.~~
e . e e e J a > n ws eaw e e se em o e eeo e. a. a. n. e. n. e. a. e. [ o ee e e se me e 1 & ese a a l eem a ete w as o ew em ep
~~= ca Jw en m = == cm e a e~~
c m a a >J s e me sw sw =sw a ou ==u an= === l eama Oce e. e. e. e. e. e. e. e. e. Jmow m e. ea e e e u o e se es e uv m a ense kw use om
~~&& am e 400 me Jams we .~~
J > ae m. m. e. m. m. e. e. =. w ee asa see e e se me e = e a e e == S eW 6 es e S u Ss e JM e mua o e . S e m W e a m em em e e e e e a m m a s E s I O u s.e a wbeE
~~.w.~~
~~w e e~~
.e $ f al.' ,Yl P%. S =eC> wM w =W e s' t e e g E .a mee CMek M e
~~e w C kh Swe3 e n skuuk&P&&ph~~
~~w w . =z w w e 3~~
~~. a . w e w 3 Sb E&~~
~~3eeWCensocen he ape Q O V e e ==Osaw~~
&m&mhO =O . mme ears e . O ES .HK eu .
OO 5 S J bb u & J em Csem um EWm N e M m p e w s F > 6's a W Em CMS 9 m J6JuJesJaros umg Ees u wo g a m S e = B E
=
E O em e e e e e e so G mmm m s w ess - a e a J se Je p => O > pJ WE N
~~& ew e 3 SQ p so > a a I-B-56~~
Table B-2 (Cont.). COnhtLL aFTCALF & DDpt 3919 FIN $f OU4pftp 64534 = ul5CMaaGD. WEPOST FOR OVEpaLL WEWTURI FL0alDA P0eEn C0hPOWATInh CCamugtTT STRUCTutt STUDI AT CRTSTab alvEn Pouta PLANT
========mungEm OF INOlVIDHALS======== ==**===PFM $00aar PETEn====== =***tET WEIGHT ==== ===*Def WEIGNT=====
a stan pa4CE STD DEU T0T ate mEastn3 TofaL mEasta3 Taso4 TOTAL 302. 40.3 ti.= 61. 19.09 43.053 6.154 19.3890 3.1599 4 s I i un 4 4
=
0
e
Table B-2 (Cont .) rna=, e,i, -. s e a .e s n.. 8,1, na514 = COdf ans, es s peit t p e.ee SFCupp Ouarte> vr eel tep t Fl.teW l sia P le> R rn**P 3M at tin siv 6 s a L3 t".sm ees= t iv % Twosc ro w.; %fue t at cs y% Tag. pl at e Pner e pLagT
...--.. sum tis as 46- l sei g y 3 sip a f $........ ....... ppa sq.savs ptith...... ...*wFT WEICHT.... .. *097 W F. I GH T..= = =
raa0g e .ef. 4 6 le a1CS STn s 6 v Tot al. "F. a 'e / s 2 TntaL stanse2 PHYLUM peip gggg g 44,ggg g,965 4.3342 1.2640 PHILUM FLaTTh* LMt vf ut s 0.038 0.006 0.OnSe 0.0083 ouIn. $p. 2. 0.4 u.. 9. 0.55 Pw y l.u m eCataflMFa 0.nqu 0.00s 0 Goel n.0016 Uttp. KP. S. l.6 v.= 1. 1.22 Pac TLee stPuncuba 2.816 0.561 0.4544 0.09n9 U410 SP. 49 9.8 0.* 97 85.75 PptLUM awesLina 6.547 9.309 1.2752 0.2550 g Class PtLvCuaETA FangLV a s a krs.L 3lia r 3 as s h a ht l.L a g ee t Cnt.Ok 9 3.s ts . . S. l.92 g %CteI ST 0* t'a l sca 3 anngLPHI 1 n.2 o.. l. 0.4% Ln FaulLv C a p t g e g.g. t n a p. oo %Cv P.soposertus Ps.af f PMOCTUK 4 G.6 0.= 2 0.u9 Fa 85 LY DHulCthaF daupgrga sahnulpea II. 1.2 0.. %. 2.87 FaulLY F LaPf t.LICD'pIDaF Pipise ts F aHCa 8. 0.2 0.= 8. 0.4% Fa4tLY GLTC6 4 thae; Gt.Trrw a a=6*srama 2. 0.4 es . = 2 0.89 Family m a Lip e = I n s t:
' 3.29 'k__ a alothe.i ta
Hrnsa II. 2.6 0.= 0 Fwaarutpahtfpl5 a sip p lCa g a 4 l.2 0,. %. 2.37 CH CLl a8".6 3,s.a t e **'Off a f a 34, 6.m 0.. 44 15.28 C' F a g li.y ne we.Inal CFraTo***>l4 IWwifaulLIs S. 5.0 0.. S. 2.24 l 14, ne.a pr e s cess,vr.n g 2 0.4 n.. 2 p. 9
~~.. . s F a. 5 a 2.. s.. 0.. 20 i2.52 .~~
I ' hep 6'IS 5dCCIgra I. 0.6 0.- 2 0.r9 i 0.= 4 ce) PL a f f '8D.as t I S t*da t e l f.I l 7 l C_ . .l ..
. 6,7 .,,,0. s.. 3. .I.4 Q Fa4ILt e>#1u PH I n a r bl8+pa Two C'erwe a 1. U.2 p.. 0.4% -% ' n=upw a g gf P'stM5a ab. 9.2 U.* 2#.
I. 18.80 , C_7 t'autLe eu,pg=3InpF C7 M aPLnWDLnyt.og it09135f tlS 32. 85 . 4 2.= 28 7.70 c3:$ b
~~.a i . . % s.~~
gra.L'* P t .u % ee nsos a a. 1 0.. l.4 0.- 0.. 2 J. 0. 8.84 4 Fa4ILY p a ne s se. t o a 8 av s t"g ht.a i e t s.oe 3 n,, o,. 3, 0,43 D adla.T P 68'r I L'< p at T I Da 8 po* C i Ls ern a. Th % J.su nom i S. 1.6 0.. %. 2.24 r a = 13.v poet.f holi.at La P 8134 61 I a roaws g3ag.:s t 0.2 g,. g. 0.a% L : . . .. . .. . , ,, s s ... ... ... ... 4 l. ,
~~. _ ---.. . . . . - - - ---- ~~ -~ --~~
Table B-2 (Cont.) Cn= = t e.l. = >.i r ai.r s . ein, 141, h t Pfit i e s*h 5ttemp OesteTFe Ma%34 = CH9 B ples, VFwfput 6 L9klDa Petwt t (duPumaf f ul teve naLL Cel4* ele t T V MTeuCtHet s t *t u t af a l'vsf al P O Wle Pout p pl.a N T
= ==e e...b u d et R th t hlel v l16elal $ e ====ee .. . . . . . p p k 84Hae t et1.N====== == =wt? mits.pT==== ===anAT wilGhT===*=
h MLag kaD06 sTU DFV tot al, pea 4/p2 TOTab BFaNpS2 TaE0m laFILV S Fh Pt8 L I D a t t'4 8 0 SP. l. 0.2 P.* 1. 0.4S FaulLT SPlumenat Pul.ypona dt.nsTFWI l. 0.2 0.= 1. 0.45 FarILV S T L.f.B a a r MTLLI% SP. 8 l.6 U.= h. 2.S8 FAMILY T E R F.* El.L i p a E Lf5fLLa al.d4 9 l.0 0.= 4 1.64 Pista Cpl %Tafa 44 s.e 0.= 44 19.64 STul'MI,H50*a HaWTmataE 4 0.g n.= 2. 0.u4 PHILUm mut.tuSCa 0.8748 0.03S4 Cla55 a*PMigtuna 0.483 0.001 Fa41LV aC a 9f MOCH I TF14 t n aE F4 aramTunC64lT0ha PVCmaEA 9 l.a n.= 7. 2.95 I F an f l.T I SCH.anrM I To4 I D a r CU lsCunocMgrom PaPILLsesus 34 4.m 0.= 31. 13.%% 8 CLa$$ 4tw a Lvla 7.4%e 3.492 4.6761 0.935) 8.aFVICasolum 3.aFVICaTHE S. 8.0 n.= 5, 2.24 [h FaulL1 CaShlTinat. Canntramrya pl.nsinawa ll. 2.2 o.- *. 2.3* Faulty CnenoLipaE Cndmus,a ulttztaga 1 0.2 0.= 8. 0.45 FaulLY L y el4 % I lis a t' l.YnN$la MVatgha 9 l.6 0.= 5 2.01 F a u l t.Y 4TTILIDar a 6 TG0sLile PaPYRIU4 1 0.2 0.* 1. 0.45 PuaCMit'UgTF5 6 2t85TI'5 34 4.R 0.= 28 9.85 I SC u s h i s's P ECliv y n g 3. u.2 n,. 3 0.45
*"5CH 8 H.% l. ate w as.8 5 5. 4.2 9.- 8. 0.4%
~~r a s II.T MUCHt.II at "HCul.a FPqales 20~~
~~4.0 0.= 4 3.94 FaulLY n%Twe luar. 4~~
- Cpaisn.% ret a v thr.lmlC4 4 0.h 0.* l.19 F a m II.y re P i s's,s. e a T I D a t PowlpLn=a SP. 84 2.s 0= a. 3.56 raulLY SE
t t. l p a t Cll"I mil a 76.8.Ll 60l pF.S 3 0.6 0.= 1 l.94 r am sr.reF povelena il.y 76.6.e. l ss t har 1 0.6 n.. 2. 0.**
~~Q g( #fdl~~
, (g{ - f 4.= t. 4.45 gQ L it b 7tLLiga gift.5 1 0.4 Tot. Lima SP. 19 j.0 n.. 10 3.40 r a m tl.y v e g F e t n a t.
CHingt KF. l. v.2 0= 1 0.4% Twatst at il.a resseant la 34 J.e 0.= 14. 4.Th Twa%5t%tt.ta si' . J. n.4 n.. 2 0.p4 21.5949 4.3100 Ct.a A S s.s t T*npo*ea 27.721 S.44% tanlLv hu t.I. l o s t. , Po't.l.a s t k l a l a t. 4.2 n.. l. 0.4% F a
~~l l.T re t p l e *er I na,.~~
roi pin et,a as e.g.t a r a 2 o.4 n. 2. 0.09
Table B-2 (Cont .) e (f.4 e* t 8 se le se e g o s.f ev 1979 e*
Ps

T e . ss- SF.CD4D 48848TD e8 9 8 % 3 m . CDMI pol. pW F R a f.I.
~~Fa.De O ne Poemt W (estpOd8Tiph V L seTIID I reggMHN B 1 % $14114 t hwe. 5T,U88 7 at CNThTSL WlVt.li Pust h PLa47~~
........*utttm CF 19 Be l w i t ei s t .s........ ... . . . . P 6 08 Fe.st a r t metta...... ....h67 hege;HT.... .... net sitCMT.....
88 p D 4 '. e# nes t.D sits ltv TeIT 49 meaN/P} TOT al, Nf94/42 TatOH CFD F j tNeg.g ag(esty34 6, j,2 Q,. }, G,Wg Ch r Pit *'eLa pl.ag e 74 $.J G.. 71 if . 4's Cu p pi nul.4 Sp. 4 d.4 't . . 2. '8.64 taulLT C*WITMilpat Ct e lT4 8Phl 5 D mLW50ml 9. 0.2 es . . 1. U.45 ry.w i f eil u m d etsr n o.'s it. 7.3 u.. le. n.se D' A st il.T Ct'Ll'*84L t Lip 46 Costushath15 58dlPLICATA l. 0.6 n.. 2 0.49 9 AmilV m aar.g hg g gg ggg
=&MGl=e LLa artrl la ley, s?.4 m.. es. 33.gp F Amig y mue3CIDAF rel.ATWorMnes 03f gL&RII4 5. 0.n 0.. 7 0.e9 FaeILT nassa>IPat ma*154wlub W l8te t 72. 4.4 l.. 9 2.04 H FaulLT etL i v e s.L l e a r.
8 OLIVtLLA NP. 3. O.2 0.. 3. 0.4S W FAulLY 7 t #6.P* lliaF I TD dLpsea PWOTF.IT A 2. 0.4 n.. 7. 0.09 O FadfLt THeelpar O Cha5555Pipt fa=Pasu585 5. o.7 n.. l. 0.4% PHYLH4 tes T He nP n'ig
~~$4.nh8 10.084 14.1970 3.4%96 CLas$ Catestate.a 54ACLAS%~~
e L A COST A AE. a ne r.6.m isnPona FAMILY 8tGlpA6 U4fD. SP. 2. 0.4 0.= l. 0.S5 F 4*ll,Y lis'tTD I p AF 5 2.n?
~~Q- q=In. tv. 7 3.4 0..~~
~~g. F a m ig.y spaa p wn= Afloat; S.94 RL-tougn. %P. 27 S.4 0.. 8%.~~
, Tr-) Ok P t'M A.9N l P4(' A i i&*lLT a n e t.l.15C ID A F Uul4 $>P. 6 l.J d.* l. l.in j g_ Faulty amplTM9fDAF unip. SPP. 29 S.o n.. 23. 9.73 I V.--- l c )aslLT auk lasat N. 4.. 4 2.Sl i Unle. SPP. l.6 LVhlA4455ftt4E i l @g g) z 6 4 m l8.1 6 Aull,1 o,1... sr.
~~#ELITtnSt~~
~~e. l.a n.. a.~~
~~B. B.se l.50 l M unto, sy, 4. 0.8 .s . . n.nt u i., c a pi .e~~
~~,M F a elt.T ALPHeIQaD 0 4%~~
atywe ns w6.To w..Cwas t i g I 0.2 se . . l. i Curs' a . . . , s. . .. . l.. ... i. . . stes t es. 58 . 7 u.4 n.. 7 0.99 w F A s I t,T ( Al.LI A taa %% B P AF 8'une.o o.g a ap s t e:I4 't . 4.1 0.. I. 0.4%
+19 t . .s p . 4 8. 's n.. e. 1.79
Table B-2 (Cont.) l Cuw ee ..I, ar real.s L e l>c v =T9 na 5 I . . C.. Tent. .P.... . . ,
~~so fn=0 onaar.=~~
~~vf.nfunt FlpayIDA Pet~~
~~0.P OfeW Pe t# a T Itse revFpaLL re sm u'8 N I T T 51kHClukt siunt at Ceef5 Tab #8#ER PouEN PLa4T~~
= = = = = = = = m'f 3 P E p De i mO l v l e ft a s.s........ .......P&W s*3'8 4 b. set (Sk .eee. ====wCT WEICHT==== === 04T up.lCMTeeee.
TARDN = at n't #*>6* 570 CEV fnf at. me' au sm 2 INTAL mrautm2 FaulLT et I PPHL T T I p a t H I P 809.T T D. Pl.t tles a r a u T H a 104 20.a 3.. 49 56.?? THOR Fl.4BN fl'a%els 6 l.2 0.= 4 2.40 "NIn. SP. 47 82.4 0.* 11 14.15 F a 4 t l.T u aJ i n a t. l.IH14I4 SP. 8. 0.2 0.= 1 0.4% F a u gl.T PAGHugnar Partinses 4PP. 19, 3.6 1.- 80 9.8) paulty P a t,a s .eum i n a r pat ap er h>:s s e 5 B N T F e d EHills 8. 0.4 4.* 4 0.45 P a t,4 6. s' ele 6. f E 5 PHGl et lu. 2.# 0.= h. 2.5% Pat a6.pne t T> $ %P. 3 0.4 0.= 2. 0.u9 PFRICl.1864F4 SP. 9 9.W G.= 9 4.02 nhl0. SP. 1. 0.2 0.= 1. 0.4% t-4 Faught P i nhte tMFh I n a p 4 Plautta SP. 3. D.2 U.= 0 0.45 08 Fa4ILV pouce.53 5 p a 6 I andtnetTER ST*4EtalCUS 2. 0.4 0.= 2 0.99
@ panggy gangngpaE tupiPamOp6 Hb #D PMES$'95 6 1.2 0.= 3 l.10 nepFA qPE TFIAse 4 I' . 9 0.= 4 8.19 minPa*nPF SP. 50. 2.4 9.. a. 4.46 Pa*'nPFH% teP Rh Af t ! 3 God U.. I, 0.4%
peupPeus nrCleitsfat.IS 3. O J 0.= 1 U.45 elmin. SP. 330 2e.0 0.- 55. 19.85 PufLum f.CM l htIDF M a a t a 23.748 4.148 9.2953 1 0598 Uhgn, sp, 73. 34.4 c.. 52. 22.02 PNVLtle CNnWpaft CLASS ASCIDlacra 93.498 19.344 9.94t9 3.9934 HWID. SP. 93). 72.6 0.= II . 20.4$ CLASS n5f E t cuTHT's . 19.651 2.33n 2.4718 0.4956 tiplo, sp. 44 e.e 2.= 8 I, 7.A0 ,
. { ,,, __m , _ .. su. e = enw e. e m w * - *
~~, . - - . . . . . . = , - -_ a . . . . u -, __ ..._ ,._,.... . .. .. ___-~~
, .-+a. _ . . .. - .o -- .u_,2 4 e i 8 i 1 l' 8 6 se > 0W > S5 0% 9 m ea 9 W W P b .s3 >e e me a e 3o W eS US en so thI.
~~s' j S e~~
~~> E p .2 e C 84 , b $.~~
~~E >e F~~
~~9 e h.~~
er 0 9= W G > e , O s a 4 f r 8 6 1 0M > ea e
l l 9% 4 :
~~I e a 6. g ,E ,e~~
g
l Je P 3
== 4 e d a 'i W g 4
IP g eJ g i ee @ s 0> e 4
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~~- .===~~
~~a- <> e~~
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~~J . 4 4 "e e~~
~~=se d .=~~
4 *
~~*t*~~
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> e .*
~~am 3 * {~~
'a
~~11 C .* e e~~
-a f' w PE3 e e b em 9 b ha **
~~e e [36' C he~~
.* lbe == ,
- y&1> 1 eCL E 9 i 3&% e S
. .4 e= & a f4 ! ** e Fe 5 0 2 e E C D6e 6 2 == a e9W P o .grs e u
~~e a a l J> 0 mb I 2 0 E e e g~~
~~> 0 - -n 9 9 m e~~
~~to en e e E . i : ;~~
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~~$ D 9D *0 TY !~~
a
~~- =~~
2 J ]m.M olu L L@ , s= N I 6 I C
~~.& e- # aI m- e= e= . se c~~
A 23 ea e N ED > b I-B-62 I 4,# y _- - ,. ~,, , 3 3- -3 ,y -- g,. , ., ,- _m ,_..,,,,,._e._ ,m ,y ,,._,_y,,,._, , ,-,y__._m_y.
O3 t = 0% M cran r#1 P e .3 F em J S A t= e e e ' e" LJ eSe 2 tes O - ee Ua e Ee C> C a w O QV.B- - r) g b eY Cp e 4 0 C e M 9> e
c=
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~~A .a ae p 8> O to 9T~~
~~E 4 t= o e 3 sue J.~~
G 3 D e eS m 3 44 3 9e p9 de ** e ce e est d a* e3 ee F* s S ea4 5 a
*=
e 8 9 0 = pm == Pe p= = d m m me en a y-** C* #F f* =9** o e o e e e e o e e e o e o e e o e e o e e e o e 7"o *e e e > Q t e e
~~> = = e C 3JO O3 O%~~
~~l. e. t 4C O O3 9C OM e= O e as se at == == O C 8m O 4 3>~~
3 9 6 44 d 8 ab a 4e 4 == /. > e a e e e o e e e o e o e o e e o e e e e e e e e e : a ee e e e e o
~~- ea - ee - ee = Nr # = 4 * == y e * .= = y =. ae * - a= = e6 %= =#~~
~~as y's *ie - 1 >J e ee .a s> em e J~~
V" 1D e J 21> a= 3

9 8 9 4 et 8 9 0 8 0
* : 1& C24 0 4 4 0 0 0 0 0 0 0 4 e eet t t .2 e 2 6 W tr. E 0
~~o e o e o e e o e e o e e o e e e e t. e e e o e e e e e o e e U~~
~~2 C3 Cf 30 3 3 O S CO e332 2C C Cr O e C3C CT S&~~
~~b= b 3 heSe ee m : 4& a C. es o= 0~~
~~*OG S e J1&2 ee e*~~
as e y 3 ee e e se se e se C* pm == m a == .= c 4 > & 8 = e == am e e o e e e e e o e o e e e eF E 9 ? e e e e o e o e e e e o e e o e e N O 3 0 = O @O OJ @ es as 3 g4 am o en se C O 3 *O e se d's *3 2&O 33 3*
F *= el E ee C Es e n U C3 9 Ju e ab S C 0 e e e e e e e e e e e e e o e e o e o e g 4 e e e e e o e e e o en a en == Pe f4 3 m as se PD e em Sm e m =D em de P@ @ m e es f% ee es em
$= 0 m fe F 4 1 ee e se M en an en s.
E
?
~~E s 0 l u =M <~~
d. a WE e M l -s u = e um 9=
E- e I= In: 5 F.
e 3 e r C3 he a* e e , e 'eA d W> es & W t
~~= = . e a ee s 3 wt 4 C" . -~~
a' e a J == is er F &Q "4 3 int 4 a == 4 == e & e e e meJe to == at .a se eW& T. C in e ee e E* =bP 2eCe e& PT'd b *
d & * = wi == E J 4 e!e# 3 5

se ae *a 2 L a' 3 J e TK eJe bA2&a '
~~l i~~
^ ** 4 em W == la: b'Je=e&76=be2C d a 1;cJ;g m3 ; w* e /4 = e e3 e em LJ# .3 e J s O 3 & == a == ta a u t= ses 6 e == =# C&/
~~buJ #3 e e MU =2 &Ja = g g s e es > = > e L = e = 'a *a>e F V.~~
-ses F e = >v -raav=C4. - v .3 er eJabb.* -r . v. a s J e e4 E ee7a=#keb *b o e 01 2&J = a tR a d & == 4 eW *= T S ea eCOJe e ;sm M%&e e e 4 = == as : e2 a& J#=3C == J O 2 e e & J to OO4 ;& 2 #*
Q e to 2 4 y Q wa >ee e a e a J == a aa v. : aE3 UJa a # > - C !. EG /t = = = Q G e 4're 4h 3 = =cea aaa a cea e : e. 6 se =.> e.er-eCe 2 eemer a--eeseee #1 3 O W 2 == J B 3 J, t U 4 e # == m OC=& e&d J J ee.Ja aT *# 2e
~~'2' *=~~
Ju I e ae=b a e*Cme 4 mm aC* w C. e A y > f an ay a o C E&*
O .C3& E C e w => J *

e == F. T > & W W e a>-W e em C4e a e' C== 0= &C 4 = 3 a- > r= 2 2 M FJab we 4 >A& M> e>J>>>2>e>TJp eh >eU>s>&>e &2 =3 t ==*
N aC 48A 43 fJ>L3J9 JGJUJ.JJW .J. S U .J. .! d a 7 .J. = C .J. 2 # .J a S 3 3 -J & & 1 eJ. b : a= I - e s .J. B = - - - - e - e s a e a e a 80 F a a e a s a a a y e e e e e e en e e e a e e a e e e e a m e he h In tm num O E # ab s e th b bm Esm b em nm
~~@ 82 4 =W pt => 3 4e S e >J g e8 'e e 1y b~~
I-B-63 e
e Table B-2 (Con t . )
...n e lot, ri. ..si. -.ii..r 6 or p .. r e nP s,Cn=n onamT..
m a s s = - i. i sc a s .... flW F 9 s t.g. W D 4Iute l F s. usa l u n PHWD ti CtlN Ff Hs 4 f if188 rowmeis t r y STesuciner Atting af Chv%Tal. FlVD.9 POWF0 PLa4T
'e=======4QteDF DS I asp g W l t+4e al.S e = = === = = *ee....Di k %ues a ul Pt?69...... e e. wt? targCetfe .. es e.Og g wrj f:eef emme.
fashu e me .s . w a wt.t STD E)FW f t'T a l. PDa4/42 total . neam/42 FM lO4tasPlot stFTs useme aWCHla t. 0.5 88. = 0 0.In Scul6 8 6.Pi t buoagara t. 0.8 v.= 1. 0.1h
~~"%3D. SP. la. d.0 n.. 1. 1.83 rael%T $ T 8.1.10 a t.~~
51tLl5 58 3. 0.4 0.= 4 8.8) PMTe o' efsLlH%Ca CLa5% atvaLvga 1.e02 0.249 0.0365 0.8895 ramlLv LTesus t g uat LYoust a Hyablesa 3 0.4 0.= 2 0.19 ramfLv Pr a lpg.nm 4 T i d 4 5. Pt'ul PLina a SP. 2. 0.3 0.= 1. 0.49 r a m il.V 7t 4.41 d ip s*' 751.1.54a 58 11 2.4 0.= 6 2.40 p4 ransLv v t mit u tear g Tangs.4tLLA Calevantga 1. 0.1 0.= 0. 0.38 0.949 5.3001 0.1584 to CLast r.astenPnna 6.644 3 ranELT ma55spinar m mab$aP8n% VfBFE 23, 3.3 0.= m. 3.04 D= PMil.um 4 M T uPt1Puna Ct.a s s Coustacra 16.747 2.392 4.0037 0.5117 SumChaSS m ai.a CU $ f w a C a nulet # Cumart a "h FaulLT Ol a st TLj u s t. UmID. SPP. 6 0.9 0.= 6 2.27 e}e ns a ragalparra
%elMOWDEN MO408 tlenp ufJu a tigtn. SP. l. 0.0 0.= 1 0.30 Onprk 154Pinea paulty inotrtDar
~~12. l.7 U.= 6, 2.Al n*10. %P.~~
~~gg F an t,, L,t ,,,SP*e Geot:# amPoetPHna~~
~~. s,.~~
~~a6 estim a r I D a p. 8. 0.0 0.. .. . 3. r a n g t.V amptLIbCloa8.~~
~~'I N I O. SPP. 73 3. 3 n.. t ee . 3.40 f amili a4PITMngpat 0.49 (ae)~~
~~L_1~~
~~.. . i 0 s i.~~
~~F e m t e.1 AHuthat~~
~~. 2. .. . ) ... i.~~
g-g umsn. tpp. 16 2.3 8.= u. 2.1% (6 ramILY CustPuttnam o.ie p=In M'P. I. n.1 0.. t. q# Omn6 m De f a Psesta rc () e au gt.t se rue snas se pwo us me s s =C 4 a e t. g s 1 o.g n.- g. a. se an owo.us 36 m. l.3 6.= %. l.d* 9antL e es.L3 a ass % snar he,or.s ei t a p o s s a. e s 80 t.4 q.- 8 2. r ea 6.=su. %P. 4 n . e. 4.. t. l.15
~~-m.w-e.=* *- ~-m.=* - - * * * * - ~ . e , . . , . . . _ _ _~~
Table B-2 (Cont.) 19ft C9==*e,t. **YtetV 6 Dnot 3FCuan QUtb70s w 6 pe s> T t eep DVD W al.B. maggg = e g bru a wt.e D Lf 4M I ba Pel et k f f*b Pok a f Ifsh. Vf%Tuei ("#4'841TT AT>t#CTow*. bTp0f af C6tAfas = 3 86.m Prist's PI asef
=...... 4.eenFm rir t **f e t y g we s s.s .......= ****Def WEICHT****= . . .. . . .s 9 9 Lau str es19w.....e =* e=wF T wt.f r.ne f == ==
etagss2 TOTAL nFamin3 e t.4 % m a a..* STp sie w Titf aL as Tatog Fa*ILV ufPr01TilhaE 63. 9.e 0.= 21 St.le F I P POL t TD. PLtekaCa4Twa 4 U,* 0.= 2. 4.99 Wild. % .P. 9aulLt oCTelDar B. 0.3 p.= 1. 0.34 ut.1 s t et.h f aQUtt.n534 3astLi P accep s Pa r. 0.0 0.. 3. l.53 p ar;pnus sre . 4
~~3. 0.3 0.= 1 0.3a pelo. SP.~~
F am it.T P a t.at erig g p a t, 9. 3.J A.* 4 1.60 PalateemFTr$ SP. 6 d.9 e.- 4. l.97 Po rtfLinL4f 5 SP. F as t g.Y p F.m as Is A >; 1.29 7 3.0 p.* 3. P6'm a EdM SP. g Fa=ILY Poufis430aE I. 0.3 0.= 1. e.30 g C ALLIMFfTFS SaPiness F a u l t.T Pa4CE45 t hat; a8. - 4* 8.19 tz, 4 8.6 g a ma t D*:t Te # AT**ETAICt15 2 0.3 8.. 2. 6.16 e u430 SP. vs F 4mit.T s a m tp10s t' e, 3.3 0.= 4 1.46 UNIP. SP. 2.5034 0.3576 31.713 1.130 PNTLue FCHImonruasta 96. 2.5 9.= %. 2.06 Hwin. $P. 5.939 0.014 1.3745 0.3944 Putt um CPflurafa CLASS nS17. t C p T p19. A 34 t.6 0.= 9 3.50 Units. SP. f Q \)J daRM'A . . *MM"
*M*** w "** **********"N =em.= eee e e ea OeW
__. . . . . _ . . _ _ . _ . . . - . _ . . . . . . _ . . _ . . _ . , _ _ _ _ - . _ . . ~ . . _ . . . . _ . . _ . . . _ _ . _ _ _ . .- .._ _ . ..__... 4 L
~~, t t~~
~~i l l ' Table B-2' . (Cont .)~~
. co. a. . =e vras.r s e on, sete . - masis - ossewai.co. me>< r enn arcoon avsetto stefuhl fl.netDa Pose n ruvenustIs'n uttpeLL .
rthesisetsg sypHCfwpt Efppt af raySTel. stW6:9 PadeR 7L887 l- ......... .... ow e ....coms.s........ ;
~~. .... ..eee s e Asatsame e t it'ae...... ....wt? #EIcuf ... ....seef wo:Ics?.....~~
~~A w.# Teif at. measse3 fnT 48. sten #43 I~~
'3sB04 %' Ma s Sfc PFW . t
! 78ef at. S75 14.7 %#.. 184 30.44 S6.394 - 8.428 84.8393 3.*099 I i 1- h 1
~~p J~~
3 r e ce , i g t i D8 8 e Os n : 0 9 t
We) !
, k D !
t 2=e) . i w e .
! p .
o , 1 l t 1 i r 4 ! 1 1 I. - 8 L 9 ). e F
, ,, ,,, , _ .ame . . mw e amo ~ w = *==-***
_ _ _ _ _ _ _ _ _ _ _ _ _ _ . . . . - . . - ~. ^'__*****
?
~~Im .a 1~~
~~8:= d u h c-=!\ Cf ~ _ c- ; :s-(1," .1~~
'I
~~( *.T' _'.~~
~~,l y enza . -n --3 .t ! . .l 1~~
a
~~. p. .-~.1 , .g. -- .o (crs) i-m ==-~~
~~(cr;!)-~~
~~O 7~~
~~...e "o "a 's .~~
~~e 33 Ja&& es to e g .. G II 2-~~
*I.es M
~~m o em 8 E E 3 C A e C e b w 0 % ec~~
~~. m O~~
~~u E,. t = M g # M~~
~~e. C W s C~~
~~, ma f~~
i S, d. . e p ae M I-B-67 ) l l D
l i e e I i i \ l 9 0 es ea e en m W O De O% M
** ed e) SE ** O O et PWJ 9= e D e e e e em E e t% e O O O N 4e UR e e e e e 3e en ** O O O S Op W O 3
> a >J O m e es ge e @ em W O> as 9 en e g 0= 0 0 9 9 9 4 e 9 to e ee e M e e e o e e 9 > G S O se 9 8M SE D% M e re @ M Om W
~~O O e em Ee t's e e e e U ial e e e c'o e se 5 d O O O es W~~
3 9* WJ e 3e e == 9 9 9> @ 9 ao e e to eC == 9 e M e a e De * * *
~~e 4 0 ** O O se >~~
J N O . ee e > == 0 m e e e >**# e O J4 e O* e 0 0 m: O e & e pM as e O 9 *t # W e W GST se J' e - SS 3 0 9G S @ P em >e @ e *
e ** * * * * * *e en

C ee * * *

e o e * * * * *m M m'n e == e a e

O O == a ao O Me e M en O O en 9 **
S. eeC en 0 0 *= ( a e a et I W 9 E ' = 9 e 3= ek * * * * *
e * * * * * *

e o e * * * * *

I J* *

c > am se # a= c es d 9=
~~O es0m es O == e e e ce ey a= e e~~
~~es as e e em == en O Sm J 3 ce W ee Ch~~
[ a t= es a h t es Ce oeu 8&> == 3 a C C as e 4 0 e ee eae e e a 8 8 8 e 3 s eee 6 e9 0 e o e o 0 0 e e l b: aa e o e o e e e e e o e o e e e e OCOO J en CU S e4 E
~~O O e O O O OOC O f4 l~~
~~e W = 9 O O O OO O@ O O b 5 f WP.e WCW~~
~~. 6 C em l 3& B> 0 I~~
60c ae . WN l J a em 3 es a en W Me M 9 O S d M M M d S re e4NM m3 De S 9 O F ft S e e o e o e e e e e o e o e e o e o e e o e e I esi e WI E e3 e eO en en O so 9 O O O es e se ao e o e6 O es ee a e 3ee O se are = S ==m' 3 0 e
~~; ea e 3 Y C3 9 J ee 8 e~~
kbW S 3 e e e e o e o e e o e e e o e o e o e e e e e e e a e 0 O e5 O O $M @@ ee **o 'O T et em @ es SP 84 Sem -
~~== ==~~
et ce 5 M M e O E es w E 3 3 3 e C 3 3 e U se ta = r et X W E
~~& C as 's e~~
J S De C & 6 W E o >t= c = *e 2 WW e W h a o= e W = e as y e, ee Es ees w-ae =:- at at C ma J Oea r N & t
~~-= e e J .C a es W~~
~~e==c e=& C W U == 89 asc= Wb~~
~~=WuJ tar J e = e we.&e.c e & a v. 3 > e = 2O e.~~
r W34*
~~e. r. .~~
~~IC W e *A y o 2 t= p-SJ3 J EemJt=~~
~~>>J &&=~~
~~e FC33 eC*W C e se e e- &-aaAy . = = > =>=Fb>ae ec 6" C = 2 ==~~
~~-b a -~~
W J=am p CC> emeascry ww-g&yeve=gb e eT rF G e ==
4 e e as tue W>w e t- > e & W *ee C gg a a .a J. eegJJeg .ag == . .a =egy& & & a O & W& W& e5 & to 3 et 3 mm T&4WS eS a= ey -s 4 -e aaoaJ =.3 e" : S#fes Q e et J wt y te J wt a W e J C & & wt e e a I E = es re>erCe
= = J e O 8 h e9 3 == e : ezE ***3 V J B W == = C e e Jt=m C =z u s u - a e We z e & e oe en s e m e v &O s eu u3 va > & v U s= z W = rs sa n s J a *= v .a m W Weta . . . aa e mC eO aO ee Ju e se > == & y =e o e -
6 ==== ta == em; == 3 se W> eZ > *
~~aJ>mu>wa>&>zwe>JmJ>>>=>eh~~
~~== e m .;~~
~~e sg>..a3-r= . JC=4E> N y ae er ae Er 0 = o3 J= W= a~~
~~===~~
~~gg y o J e esseJ es se e & se~~
~~= J == e J== m aess J ==U==J u s esc J J J. .r J e a ves J r a r : ==E =~~
I g & 5 E S S S 5 E E E .E e 3 E e e
an an e as e e e e e an b

l en b hm b hm b e km km b b U N E E E S Eeb b c-4 33 E 3 3 3 2 =c
=> C J J J J Ja y es = > = = > >J @ em e Z T 2 E E ter ED > & & & & &
b
~
Do* d'f D 7 D ~FW Nbba a I-s-68 dfo_dJ
Table B-2 (Cont.) CommELL mETCaLF L EDnt 8919 nassa = Cnuteob urPnnT Foo Tulpe euneTFP ' vtgfuel FL0eIDA PnwEm rnePosaTION OvFeaLL CnuunglTT SteuCTuht Stunt af Cefsfat. 88TEP Pouro PLa4T .
===== = = =muert e or 3 nO I V I DIt a LS ======== ======= Pro sonner. ut. Ten ====== ====wFT DEICMT==== ====nef utICMT*====
TAAOe a mEam paNCE STO DET TOYab MFa4/m2 fnfab mEau/s2 , malmreFIS Mp. 50, 2.0 0.= A. 2.55 SCO LHPl.it % PHA44 32. 2.4 0.= 9 3.IN ra n t s,T p a s sitil n a t AalClos:a TaTLost 1. 0.2 0.= 1. 0.4% FattLT 9H T LLnrwiC g t 4E ET" E NETFanPnna 4 0.0 0.= 2 0.84 F44tLT OECILOCuaFTIDaE PntCILucuarfu% Jnnesngt 4 0.0 0.= 4 1.19 Fa4ILT Pnt.T un I n s F w a
m0T n0F, aCHI,FaTa 2. 0.4 0.= 2 0.89 LEPInasLT4lA Cf144ENSALl3 5 l.0 0.= 5. 2.24 fF.Pl0040TuS SP. 4 0.0 0.= 4 3.19 pa FaulLT Sa*ELLI0aE I Cnnut nt=Est 3. 0.2 0.= 1 0.45 td SapELLA MICoqPTHgLua 9 l.0 0.= 9 4.02 I geIO. SP. 4. 0.g 0= 1. 0.45 Ch Fau!LT sanELt.aalguar 43 544Et,La45a vgLCaelS T. l.4 0.= 2 0.a9 FaulLT Scat, g na F Gu l na t NTMOSCOLEA 1.ngc g %F.T a 3. 0.2 0.= 1. 0.45 FamILT SEePublDAE usin. MP. 4. 0.0 0.= 3. l.30 FamILT SPIOmI0er pasaPeing0SP]n Piquata 2. 0.4 0.= 1 0.55 Put,Tnnet staSTFet 2 0.4 0.= 2 0.99 PNinen5 Pin METP:#0MAAuCHI4 4 O.# 0.= ). 1.30 Fanft,1 S V I.E.i n a r 0094THATLLIS SP. 1. 0.2 0.= 1. 0.45 i $T8,0.15 SP. 85 3.0 0.= 5. 2.00
~~s. 0.= 0.4%~~
D q rgy1 Fg{3 nain. SP. 0.2 1 l q; 1
~~M '~~
FamILT T E# EMEl.L10 4E Q t LTs ri.ta si..a .. ... ... i. 2.95 .' { , , 4.14 dd c3 (d.d ' bb3 PISTa CelsfaTa 12, 2.4 0.= 10
} LJ J'] (,, i Ptsfa SP. 2. 0.4 0.= 2. 0.a9 Sturnbresnea usefmagaE T. 3.4 0.= 1. 3.11 ngen. Sr. 1. 0.2 0.= 1. 0.45 PMTLue une.s.unc a .
Cs,a % % amonggsuma 0.592 0.lle 0.2043 0.0968 ransLV a r a g T MnCH I T 0g I D a p; aragTH.ICHITuma PTGuaEn 20 4.0 0.= 20 W.94 F a
I f,7 thCdW"fMITH4fnet gsrugn rnggog paPit.Iusus e l. 86.6 0.= St. 16.01 re. ass Misat,via 49a.551 99.331 426.9005 as.InOS e.a vgrawingua goaToul 15 1.0 0.= h. 2.5%
F a u l t.V Cawlef finas 6 tawnsra-twa pg.nwenana 21 5.4 0= 34 5.11 e a a g t.T Cnw+H,enas rnun'en.a %p. 10 2.0 0.= 0 4.41 F a s t e,T s.nc t n i n a s Consula sp. 3. 0.2 0.= 1 0.4%
h Table B-2 (Cont.) Com*LLL 4FTCALF 6 rnef 89T9 p a s tle = Congfung. kFPnpf pape TiegeD Gesa*TF8 984m1D4 Pnven CnaP0eaffnn a v ga a t.1, vs.u f vu t C9m enI T T RTpHCinni. STDet at CNT9 Tab kgyre Post.9 Pham? .
========WUmmt# OF I m p f y 3 0tla L& = ======= ======= Pen sossant nFTs.m====== ====uET eFIGNT==== ====04T mEICHT=====
Taang e ataa ka"cE STO nLT fnfah P[aW/N2 TOTab Gra4/42 F 44 t l.T LYneSilnar I.T 'J9 514 MT a b lic a 2. 0.4 0.= 2 n.a9 FaetLT
~~a CT e l p a t:~~
marte n Feac3 8.83 3. 0.6 0.= l. 4.55 Fa4tLT "VTilInaE RWaCHII*U4TF5 SPP. 90 2.0 0.= 1 3.08 u nscus.st% t.a T F > a t.l s 2. 0.4 0.= 2. 0.89 FaulLT =HCHs,t n t F 4HCHLa Pungsna 9 l.4 0.= S. 2.30 FaulLT OSTNFlnaC
'JStata tuu*STRIs 251. S0.6 0.= 25T. 104.34 FaulLT MFpFLIOaE d CHmI4Gla CoaaCTafa 8. 0.2 0.=
~~0.= 1 32. 0.45 S.2T g SLN6.LE PO4FICHa j ), 2.6 tzs F a 4 tl.T V t;4 0.# i n a E~~
~~Cu t og *: CamCf.s.t.a f a 1. 0.4 0.= 1. 0.5%~~
*J "spCteaala CapPECMIEWSIS 1 0.2 0.= 1. 0.45 CD TeamsD=FLLs Commantua 3 0.6 0.= 2. n.09 Cha53 C.45T unrun a 42.000 0.942 30.T040 6.1540 ram LT wastunggnar unstenra sp. 1. 0.2 0.= 1. 0.45 FaulLY esus.L t H a F **
noLt.a Stug4Ta 2 0.4 0.= l. 0.h FantLT C he pi n'H.g naF Ce9 P lltHl.a acut.F a f a 6 I.2 0.= 6 2.4A CpFPinHLa earHl.fj%4 )). h.6 0.= le. T.at , !- Ca* p t not e vs.a ss a SS. 33.0 0.= la. IS.an L Fam LT CawCFLs.autoat ,- Ca*CFl.Lau r a us TICut.af a A. I.* 0.= 4 l.52 c' Fa8tLT Cregruginat CrulTHlUm "4%caeum 12. . 2.4 0.= S. 2.58 FaulLT Cn g=g a. ac. . LHs seme elTW6LLa neroeune i,t.i n a r
~~.....,F.,a 9 2.~~
~~l.. 0.4 0.= 0.= 4 2 l.., U.N9~~
'C r a u f l.T r s %C i sH.a w I g ua r t a 5C gne,ap t a s.II.p um 3 0.6 0.= 3 I.94 FautLY =anc t us e,s.g net Ce maecime t.e.a aplC ises 49. 0.6 3.= la. 4.If ,
~~c J F a u t e,Y d'se l r i n a t~~
~~=_gy CaLaTuop* Hem ntfarasH4 8 3.~~
e.2 0.= n.= 0 0.45 gy Houses. PIN T ampe gst s 0.6 1 l.44 Fae 1. Y =auaminaF W gaggavens vgora s t. 2.4 0.= a. g.42 y y ra*lLT aafargnas put.841r** nops.graf"s 3. n.2 n.= t. o.4% y a e l t.T T H$*W I f at rwa %%I%ptwa rampapeggs 2 0.4 4.= 2 0.89 pH Y l.tle a M T steenP'tu a F. ass r ..st an a 4s.ieT . 029 ii.iSi2 2.2Tn2
e e I $ i rl
~~.. I.".~~
d
~~>eJ OkJ es ee 9E Me EW ~' Q .~~
J eE k9 S 3w o-me W Q _.>)' C 3 O PC e >J E O, ,
~~- 4>~~
~~0 r ) 6 8~~
~ rag >W f 3 ,
~~Ee WW~~
** S W A
~~[ J B WJ~~
~~.e e em Se OC r 4 6e e 9 J~~
~~E b~~
~~. . . , > c , ..... e soon . , e t,e .~~
in? 90 e 9 em , e e . e fe e e e ee e S 9 9O 9 e e m e e e > e e se e e ye e e O e o e e e e e e e o e e e o e e e o e e e e o e e e e 3 0 t eneeee e pOC3 OO >
~~& G GS e e e se O e e se > e ce e m em se 9 e>~~
5 0 0 W3 M SS O tM 3= te e- e e e o e e e e e o e e e e o e e e e
> CA JJ e e e e e e e m ao e se p == e e ce e e pg c e se h se fe = e C == ea fe se se se se en se m se e se C > m3 = es hw ee Cd r> em a b*
et OF >eu e&> ===K eeee hCaa cce e e e e e e e e e e e eo e e eeeee e o e e e e o e e e e e oe e e JbCW W WD S
e o e o e *

e o e e W

e e O e e e e e O O e e e se e e O O se O O O OO O Uk > E ae
~~>WSe o em & Ce fe &~~
y a6 e me e em C & 5 0 + Ja&2 =4 gu gg g d eos e se e ce e se a E 9 ce ce a M e to re e M e ce e a e o e e e 4f5 ED E e. e e o e e o e e e o e e e o e o e e t.m = = ee o e e e e o 9 - m o - e ~ .o .e .o .e .e ~ aOsa OO E em J SO tse C SE e 5 W CD e JW t mU E 3 0 e o e e o e e e e o e o e e e o e e e o e e e e e 4 D 0 4 m se e m se m ao e p en e se 'e e se ce y ee as e se ce se - m eoPe M es ao eg e se a e S 3 t eo W l
~~? I a~~
W C U l WB 3 ee > ( W m3 F W
~~e e emp W n iel M e #~~
\ m O e e e 3e e UT 3 & l C W lap es T se OMJe; a W i i C se & O ==*13 #E e E CW = = . W W 4 egF e i
~~^ u ne = w > a e e a J_r e rc=:=-~~
W er a= 4 LFJ e** e e tal e = we er W e me C O == fel %l J E e emmW oee>J: e! *E"
~~y me & E eW J e W U = W - Q e E~~
~~Qc ope: J == s up ww~~
~~&c a=~~
~~J e C C~~
~~== a e e=~~
~~e O~~
*Z W
e
*C = x *E *> ==
~~0 Cswa e&am>&m:~~
~~=3 km : &2eeJ =**1*1C1 3~~
~~e O & reCu e-w e eb ew e e J sL > & a m - E & s 3 ek semesseWJe&**: -Cw e e v = c zs,~~
~~- "a "~~
~~u y~~
== WensJeeC&paetews-&-&w&rkva-s: r EJMeC 3 v. J B 2 U M C E T W & se & WW &Wtt 3 De k M eM = ven J EwC &&JT3=Fe eft eft W W W J se & > > J e " # *Y ""3*.
J ae J == 3 e e C en S & e C eE=J=*88 C =aeee er=&w *= en e r e en ee seOU eJ ee see4 wa . aUe ace : * ***!
a U eaa C JC C O C& C O O C C C 2U 2x23C u & a T 'a g > J e3- JM = = =E = = = = = = =g &&&&W C &> h Et b, I 3 he MJEW hb3>embr>B>re>R>Wp3>WW D=Je 43J=J J: J2J=J W>p>wa>JJJJT>&>=eS:4 J J3J2 Jee64 J 3 J 3 J > > t "E* 8* S *h M U m= m a = = m = = = = = = = = = = = 3, t es es3 s ae a e er a f 5 E a a sw a W 8 e . t g t= Je JhC e we e e he e e e e e a we e e
b l e Uh uc= tse ob h h c em h em h h h h Ce in b l sed E2 3 E SEe E S g
~~,g3 -> C D =G C C 3 N ME se e et i~~
ee en i H = > I-B-71 e
Table B-2 (Cont.) Com44'LL mETCaLF 6 5Dnf 1919 maSgm = Content wrona? Fps ygggg gggPygp vrefutt FLHmI0a PnsF.m Coornaatton OttesLL CH4eqwlTT SteHCiust. 5Tunt 47 CRTS?41. RITF.m Porrp PL4m? .
= = = = === =m uc ht e Dr I Nn I V I DH a t.S == =.-=.= .......PFR SQHast_ ppTom...... ....uTT WEgggf.... ... 0e7 #EIGNT=====
ratng e aF44 WANGE STD OFV TOTab mEause? TOTab mFattu? F ae f f.T P e t.a s;mng l H A E P al.4 F et*** TF S letreatnlua
. 4 0.4 0.= 1 1.30 P4La*ankFff4 PHGtn . 2 0.4 0= 2. 0.sg Pt # t re.l eF 465 AuF8tC64HS l. 0.2 0.= l. 0.4%
PtolCl.l*F4t1 On4GIC4Huaf44 4 0.8 0.= 2 0.e4 ' ugIn. sP. FAMILY PF.NaFIDAE
3. c.h c.. 2 0.49 Pr.marus $P. A. l.2 0.= 4 l.79 tuaCuTPegagn4 CouST#tCTHS 2 0.4 n.. 2. 0.e4 untn. sp. 4 0.4 n.- 2 1.le r a e l a.T Pl449fMtNIDat Plhelsa SP. 1 0.2 0.= 3 0.45
>4 F a m i t.T PneCrLLaggnaE I PEtmyListuos sp. %E. St.2 0.= 9n. fl.14 Da raulty pe nC D.5 % I n a r 8 4a9tDrafF# AT**ETAICHS 8 l.6 0.= 7 3.05 'J roulLT 4Awi4144F bJ 22.
FHETP44npr.us orpart%HS 4.4 0.= to. 6.40 4 8.up 4 *nPF. PACatent 8 0.2 0.= 1. 0.45 NFnp44nPF T*.t Aw a 84 3.2 0.= In. 4.60
=Fi*pamopF Sp. 4 '8 12.0 0.= 34 34.95 P A4088 HS PrClpt 4 T ALI4 S. 8.n 0.= 4, 2.24 Pa40PrH5 %P 6 l. 0.. 6 2.68 gjjj) . i r .nP..nP,.us a..Isii 4 0.2 0.. i. i.30
.__ Hulp. $P, 144, 29.2 0.= 138 40.89 PNTLH4 FCH14nHFA4STS I2.262 2.412 4.0094 0.9439
~~) ..... ,P. .. ..? 0.= ,0 .2.4~~
'C P4 f t.H4 CMo*9aT4 Class asrtolatra . 31.921 6.185 6.1202 8.7440 netn. MP. 44, 13.2 0.. 19 15.94 ,
C;; ) Class osfrtCasuers 4.446 1.209 3.4044 0.2e80 u4tg. Kp. 14. 6.0 1.= 13, 4.34 w (e! hlb) H!sa ===>
~~.=2 e~~
~~,s i~~
Table B-2 (Cont .) ; J 4. ' ' Cimes.LL es tcaLF 4 Datif 8979 > e4Sla a Cnsetent oppnet Ft'a feelDS ##8ette , FLnesca poeta cnerwaf f ne agreaLL , wrefese t -
~~ro==* s t yg steneguet. Stung at cat % Tab eters PaneFe ette? .~~
........masept e N t en t v i nga s.s........ * ===== -Pfp soester *Ef t.o. .=.. ....ett etICeT*=.. =***Det etICsT=====. * *Ese paeCE STD D9 9 70 Tat ernesef Total eresset Tatne vnfab 3193. 350.6 97.- lose. 345.04 618.334 134.347 493.9441 99.9009 k
~~t t a I e4 0 tW~~
.E q L 1
~~t I L I t 4 E e a~~
\ , L i
~~. I a~~
i l I 9 OM m 95 e Ps es e d O e a awJ er m e a e = p> W. O M m e h
= m .J EW e e ee o e es WE e e r e =W = 9 e e =
OF W 0 9 O M e a >J p e e m se M M Ok > m e @ . E @ W e M 4 C S 9 e SW G e m o e e o e e - e e e e m
=
0 SM p SE e > es e n e > kW G M @ af m e 2e ee e m e a o C
~~u. e e~~
~~e me e M W 3~~
> e m WJ e Se m e e -
8P * @ > . e e e a m o e M S3 m S& e e e e
.E O e e a d J a > mm a e em m as e m 3 e E e e A e m se y ** a m e e W 9 9 W e e m of e em m m em e * * * * > m m > M e e o e * *
S 8 8C *

e * * * *

e e o m e O C es

e em e e Om M OO d G 30 0 G O O M e a em O 8 8 >
~~S 9 9d W Gs~~
> 0 W e e * * * *
~~3= Mb e e e e o e e e e e m M~~
~~= Ca a. e e o e e e~~
e m == = mm e m em > == < 9 es = M e e O = O - m = C = h k. .J SW sk -sW d Cr D.O S ee ae ee e e e e bC&Wa Oc -22 ems 9 e e e e o e e o a e 3 e 3 3 o e g O e g e e e DO B e e O e o e e SO O OC e e C e O e C o O e J. h Q C 9 & S O 99 4 b - C C UN > 3 Met. b. mom C& 0 3&W > WCC ee me e em C d a d Je&= d e m e e e e a p me m ee m e e e e e o e e o e
E t e e e e e e e o e m O O 4 S e e o e o om o og g g og - 30 e e O e O g a e S S t .N O e O
$ ed E8 d . 32 e 3 v ==a~ .o . * * * *
e
. . e *
~~e e e e . se o e~~
~~.e . - . e - . m e~~
~~m o~~
~~.e .o ~ - . me m o mm -~~
~~m m em~~
=
m.
~~~ m b~~
F
=
~~c W~~
~~= . -~~
~~u .~~
~~e . - a~~
. . W 2 = . . W = E 3 sv<. -- = e -
~~e.W w e .e . . - a a. .e .s e.~~
~~=-cm .~~
n
~~.~.~~
~~e.=~~
~~-a- - .- e =.~~
~~s. o,. =,.-~~
~~u. a. s, = .. . .: . e~~
.<. =.a. .e. . .- <a . ..<.. ..--..s a...c- ..a2 a * >=a .w= a e.-. ., < a..ve uw -e-u-:=s -s c a =. o,-a.. =C<. ,.s e aor.n.a-,..- -ca.=. - * ....su.u..-- e s e .aa--=5 rar: =oue -n -=; .a a= ,=-.....es= m,e:..s.see . * * .n se <
~~8 v u.~~
~~.s . s.~~
o
= .e.s. ....-.=-o..... rews.a,.,e, 2- .ua..-c.ee: <> .e, -a c... ..s..c- < u..= .. a_ <:e_.2;..a. ,-: 6..-r.= b* . *
~~u o -2..v. CW Ja U Q > J L* u~~
~~#. J b, <~~
~~EC JW m S & W &~~
~~.a a = .J ..-=~~
~~N 2 v, BC~~
~~. .= m.~~
~~6: ==~~
~~,a a..... Juaaaama=Jaca.....:..~~
~~w . o-=...S.~~
~~. . . C. . m. v.. :~~
~~aramaae - a a....c~~
~~==- -a . . -aw rav s.-~~
~~2 2- - - r 3 r 1 -~~
~~= = < a. *~~~
~~c J -e J e a- - - - e y 3 a s 3 9 9 8 m r a 3~~
~~m. .a . .a . a. .~~
~~. . . = <.~~
~~s . . . ...~~
~~=m . 6 6 6 . . . .~~
a V. M W= W = = =a a y -> J a J.
~~=a TV m C. = =~~
~~N e s.~~
. . I E Tb s H se > a a 6 w Q, A~ D 7u~N I-B-74 Dfe D A
Table' B-2 (Co nt .) coted.LL oETCal.F L EnOT 1919 Sa$le = nt$rMasCL eFPoef Fne ful0D OUsettp , e t.Miral FLUeIDa Poeta CoornetTIra OTfesLL CnemeentTT StenrTUPE STUDT af CeT9 Tab mitre P0eam PLauf .
========eUsate PF IoDITIngaL3======== ======= Pep sonner erTEe====== ====erf ut!G47==== ====Def WElbef===**
Taspe g ease eseCr STO pt T TOTag eraepet total stampet PMTLue aufsenPnna Class Coq 5 Tate a 40.04) 5.120 16.0526 2.3109 SueCLaS% Cl welPElel a Fangtg n a s.s e g n a t saLaeus sp. 77 13.0 0.= 48 to.el SueCLa55 mataCosTeaCa nonte Instanna raeILT l os e T E s p a r. Uetp. SP. 5. 0.7 0.= 4 l.50 DepFe a e pg g ptep a FaeILT sePITW0tDat P4 Uelu. SPP. 3. 9.1 0.= 1 0.30 i Fan 3LT eELIT3nar Of toegn er. 3. 0.1 a.= 1. 0.39 0 080Ee D'Cappna
%J Fan 3LT abrus goaC 48 atpur.US mrft.enCMaELt3 19, 2.7 0.= 5 l.10 as, pes"5 anseneet 1 0.4 0= 1. 0.%3 aLPette% Sp. 3. 0.4 e.. 2 0.79 raetLT CaLLlamaS5 nar.
UPnconta atFleIS 3. 0.4 0.= 3 l.l3 FaeILY 4fPenLTTgnat MIPPnLTTE Pt.Lupacatfua 14 4.3 0.= 20 7.34 Yn2Lyma CaenL3erest 8. 9.1 0.= 1. 0.35 raagLT PaGueinaE pag'es"5 587 15 2.9 e.- e. 2.e5 esagt? sat.aennetpaE P a t.a t e nw r f r 5 teTEneFDIUs to. 2.4 0.= 1 2.94 r, q pal 46e"4ET'S PnGIO %. 0.7 c.= 5 3.49 . O ) 41 paLar.enettf5 SP. 1. 0.1 9.= 1 0.18 7% {g{ 3 ' Pe e tCLieres s setettaans 3. 0.3 0.= 1 0.le ., g j' J T, P p,CLie.4Es ,,,4Gira..naTns 3. 0.. 0.= 2. 0. . i(i. h,g e.ge ne19. Sp. l. 9.1 8.* 5a FaeILT Pr h aF R O s p, se ese nt sp. 44 6.3 0.= le. 4.40 FaeILT PItenteregnar
Plungsa %>. 3. 0.1 4.= 1 6.le F a a i t.T Pele ct.I.e.n e l n a E PFTang,3gTess gy. 1. 0.3 8.= 1. 0.34 F a s t f.T peere %s t trat a=esu*sT*e %f***781C45 %. 0.7 9.= 2 4.95 s a n g s., samfetna*
s .*e t r a s.epe ns sie Pet %%+4% 6 u.e e.= 4 l.5? e t .*p a ne ses tosama 7 O.3 0.. 7 9.1h = m e s.p a ea e>> sp. 3. u.4 a.= 3 G.%) ogTeenpaenr6ns naseg533 6 e9 0.= 6 2.27 nien. Sp. Ig. g.n o,= 29 10.05 - e v e;,e e CH 3 nine* ==a f a 1.654 0.234 0.5404 a.0112 ,
l l 1 i Table B-2 (Cont.) Cet**F.I L me TraLP & Enn? 1979 ma$le = OlsrMaMCt. NEPnni Sne T4890 GuamTra , V6 g Tite l F Lues ID A PHuf9 C610P99aTII#N OVERALL CH44Hwift Statectuut Stunt 47 CRV$ tab kIVEN PHut.R PLANT *
=======empan6m DF I Wh l V f DU AI.M *======= ====== PFR SQ88 aB E #9 TER****** **== WET WEIGMTe*** **=*D97 WEIGNT=====
Taang N REau p a NGF. STil 1)F V TOTAL WEa4/43 TOTAL REAN#53 , Units. SP. S. 0.1 c.. 3. l.23 P4TLUE CWounafa C1.a55 nste.ICHTNTES 1.574 9.339 9.3783 8.8598 uglo MP. ll. l.6 0.- 4 1.88 H I tII I GEB G:3 Ess
~~=E GE c."~~
~~(W (L~~
~~c. n~~
~~;w I .?-~% s l~~
8
, _ _ _ . . _ _ - _ , - - _ _ _ _ _ - _ _ _ _ _ , _ _ _ - _ _ _ ~ . - . _ _ . _ _. . . . . _ _ _ . . - . . ._. . . .
t d', t Table B-2 (Cont.) 1919 Co** ELL eFTC,al# ene4 FD07 tulee eveetre neste = nisC=a c. . ten. 61.netna pnuta CnernesTinn ovEpaLL
~~#t uf elu t .~~
~~rnegelutty 5fWUfiUkE STUDT af C8VSTab pg vFu poet.p Plat?~~
====...=tgepfR flF ' 8 4ftl 5 3 0416L$======== ..=== ==pr e soie n s E ar t Ep.a..=* ====utt titlGut... ===*eef sticaef===*=
a atas p a 4 GF. STO tJe y Tnfat atante 70 fab stan/m3 T a triu vtif ab 427. 60.3 80.= .148. 47.19 288.788 30.244 159.3083 33.80S9 6 l 8 tuf , i' M " '" N O ' i i . , . a fbe s. L. JJ hl _:= 1 4 I i i I J G f i 1 P I . 4 .s
Table B-2 (Cont.) CuuPLLL nFTCaLF & CDn1 1979 Sasim - CQeTROL N E Poe f p f am FOU*TM 0Ua879 8 ' TFutunt #Lupipa PO Fa CnsPusaTION OTF84LL CommH41TT STRIiCTUpt STuny af ChTAfas. pivEn Powte Pha47
========mup0LR nF ImplTibHaLS**====== .. .. .=. P s y squanE mETFR===*** ===* MET WEICWT==== === *0A T wt !CMT*====
T4104 m DFau ma4GC STU DET TOTat m F.a m / N 2 70 Tab REau/m2 PMfLum PoelFEpe 36.103 7.351 10.6957 2.8398 uttO. SP. O. 0.0 0.* 9 0.00 Pufbum PLaTTMEL48mTMES 0.014 0.085 0.0230 0.0040 U4ED. SP. O. 0.0 0.= 0 0.00 PMTLUM NE#ERTINEa 0.453 0.338 0.1445 0.0295 UNID. SP. 29 5.0 f.= 14 S.40 PMILum StrueCULa 0.890 0.010 0.0935 0.0807 ug10 SP. 9 l.0 0.* 9. 4.02
>4 rnTLua asuttloa 10.212 2.054 2.9134 0.4227 8 CLASS PnLTCHaETA 00 Fan 3LT amPuneETleak I stLgmus natuLafa 2 0.4 0.= l. 0.59 'd F a m II.T amanELL30aF 00 anaRELs,a IsICOLna 32, 6.4 2.. 12. S.8)
FamILT CaPITELLIOaE CaPITFLLa CAPITATA 1 0.2 0.= 1. 0.45 mEftpuma5TUS FILIFnaggs 7 3.4 0.= 4 l.67 mFotoma5TUS CALIF 0 mule 45tS 9 I.6 0.= 0 3.50 SCTPMOPauCTUS PLaTTPRnCTHS l. 0.2 0.= 1 0.4% FaulLT ClonaTHLloar CE) TwanTa sp. T. 3.4 0.. 3. 3.52
, ungo. SP. 3. 0.6 0.= 3. l.34 Fa#ILY EuulCgnat t u u lCF. a= Tem 44Ta 3. 0.2 0.* 8. 0.45 maePMisa sagculata 1. 3.4 0.= 3 l.54 C3[-.
~~er.mafoot.ags vagnon#38 5 0.2 0.= 1. O.4%~~
~~%~ FaulLT FLanELLICepIDAE ,~~
pip 04!5 twura 2. 0.4 0.= 3. 0.59 FA9ILY CLTCt'ognat e__, CLTCEse amp.ettama S. 3.0 0.. 3. 1.22 Ctr- FaetLT consangnar CCC( CLTCimot hP. 4 0.0 0.= 2. 8.84 D FamILT MF s lH9 t h a*. 62% 2s q r.? Pfl3 Mwr,v lP ALPa 1 0.2 0.= 1. 0.45 L2C c;M ras 3LT LHummtetprgpag
C222:3 Lumpulnfwi% $P. 2. U.4 0.= 1. 0.55 FantLV mactbowspaE -
%_ maGFLeita ptTTim44Far S. 1.0 0.= 4 l.73 D_ a "'"~ rautLT m a us a g g u s t.
44toTHELLA eiert 54 6 1.2 0.= 2. D.04 - {C0:23 mes%Cw3nagTCugs empefCana 84 2.5 p.= 4 2.39 C L T = E n t s,t. a Towo441a 7 1.4 0.= T. 3.53 FangLT u s.p. g u a, . Csoafum*utI% IwhilastLis I. 9.2 0.= l. 4.45 f.a top p.s p. t 5 t. u L V t W I 1. 9.2 0.= 1 0.45 l 6
Table B-2 (Cont .) CommLLL ut TCat.F t tPpf 1919 pa5IN = CnhTROb WEPOPT Fue SnUATM OHaefpm VENTHRI PLnaloa PDuft Cok*nasTIOh outsaLL CDe*49tTT SteUClurt >TUOT af CRT% Tab MIvLk PonLa PLad?
========htoPrm CF I N D i v i Du a l.5======== =======PFp SQuapF ' lfts ====== ==== WET WEICHT**** ====OST WElGMT**=**
tai 0s a stan PaNCE STD BET 10 fat DEams=2 TOTAL *Eamsu2 NEWEL 5 aCuminafa S. l.0 0.= 4 l.13 aF.wgg5 tatta 18, 2.2 0.= 0 3.49 staEIS SWCClmta 19 3.0 0.= 12 4.92 NEREIS SP. St. 3.6 0.= 14 e.0S PLaTTuFNEIS Ouerngstg ig. 3.s 0= 6, 2.49 UmlO. SP. 10 2.0 0.= S. l.81 FaulLT 04UPdl0aE DIOPATaa CUPeEn 3 0.6 0.= 1. 0.55 UeUPMIS mtmHLnsa 17 IS.4 4.= 40, 15.65 FaulLT OppgwignaF naPLOSCULOPLos #GAUSTUS 7 l.4 0= 3. l.84 , malgraEl5 $P. 3 0.6 0.= 2. 0.99 SCOLOPLUS aupaa 34 T.6 0.= ll. 5.55 Fa4ILT PMILLODnClear F* EUmIOa Sancut%Fa 1. 0.2 0.. 3. 0.45 I PWTLLn00CE app eaE 2 0.4 0.= 2. 0.89 De U480. AP. 3. 0.J 0.= 3 0.45 [, FaplLT POLim010aC manp0TuuE acuLFafa 3. 0.6 0.= 1 l.34 y) LtP30aetrofa CummFusabl5 9 l.a 8.= 9 4.02 Fa4ILT Sa#CLLIDaF CnngE DumEnl 28 4.2 0.= 89 P.32 SapELLa atCuopTHALpa 2. 0.4 0.= 2. 0.e9 Uml0. SP. 12 2.4 0.= II. 4.03 Fa43LT SE8PULI0aF UNIO. SP. 4. 0.0 0.= 2. 0.04 Fanggy sPgowlDaE PanaPalnuG5PIO PImmata 13, 2.6 0.= 6 2.48 POLTauna =En%fFa! 2. 0.4 0= 2. n.a9 Pe30guSPin NLTEROGRaNCHla 9 4.5 0.= S. l.92 SCOLELFPIS SQuas4Ta 1. 0.2 0.= 1. 0.4S Fa48LT STLLIDar ENOGumE Ol5Paa 4 .* 0.0 0.= 4 3.19 0.6 1.34 ! Onu r05fLL 5 sP. 3. 0.= i. l STLLis SP. S. I.0 0.= i. i.22 _
, F ; I FaNILT T LP E nri.t.I n st l LTSILLa ales 3. 0.6 0.= 3 l.34 g ' h h }) L \j7 PtSfa CP85faTa 1 0.2 0.= 1. 0.4% n i ! L \.g 9l ,
PISTa Pat.mata 32, 2.4 0.= 6 2.es j (_) - [ Pista SP. 2. 0.4 0.= 2. 0.ug STMERLO5nma Napfmamar 2s. S.6 0.= 26 II.48 - Hut 0. SP. 9 l.8 4.= h. 2.60 PWTLue mollusca CLa%% A*PMinenwa 0.494 0.099 0.2444 0.0529 FantLT acagguncugTomgna6 arawTduCHIT"9a Pycmata 4 0.0 0.= 4 3.79
~~< s m II,I IFCM*ocalfuginnt gNCMooCHIrng raPILLnsus 38' 6.2 0.= 30 13.38 -~~
~~CLa55 alvatv3a 26.423 S.285 88.9419 3.7922 r~~
~~. 9~~
Table B-2 (Cont.) Cusht t.L mEfraLF & ePDT 89T9 stPnuT Free rountu nunpTpp easIn = CONTant VENTust' D Luk t pa Post k (n=PnBATin" OfffaLL CommH9tTT STuuCTueE stunt at twTsias,ulvEm PowEn PLauf
========puante OF 1=utvtrust.5-======= ~ ======= Pen squarr agite====== ====wf.T WEIC47==== ===*0A1 WEICMT=====
N MEau Sa9GE STO DET fofab staess2 Totab p r.a u / m 2 TaION Lar.vicaentue =UnTout 12. 2.4 0.= 4 2.30 ramILT CapotTIDat CanDITantua FLnsinada 12 2.4 0.= 58, 4.43 FamILT Coun961Dat Cuesuta SP. 27 5.4 0.= 24 18.52 raaILT LimIDat LtMa PELLUCIDA 1. 0.2 0.= 1 0.45 rau!LT LUCI4tDaE LuCIma ma55HLa 8. 0.2 0= 1 0.45 ramlLT =TTILIpaE edaculongit5 SPP. 15 3.0 0.= 15 6.Tl ran3LT guCHLtpar NuCuba Penalma 3. 0.2 0.= l. 0.45 FamILT OSTRElpaE Pd USTata LouE5fpl8 27. 5.4 0.= 27 12.0T 8 rantLT PECTINIpaE C8 aLOUIFfCTCe SP. 2. 0.4 n.= 2 0.49 8 ramILY StatblDaC 00 SEmELE P0pFICut II. 2.2 0.= 80 4.30 C3 ranILT TELLI9tDaE Tr.LLI N A SP. 4 l.2 0.= 4 1.19 rangLT vr=rulcaE CTCLintLLs TENIIIS 1. 0.2 0.= 0 0.45 CLASS C45784Puna 30.024 4.005 22.3493 4.4699 rang 6T mubbspaE SuLLa STulafa S. l.6 0= 4 l.61 FA45LT CREPIDHLluat 3 CRDPIDuba aCul,6aT4 6 1.2 0.= 6 2.60 3.39 3.0 0.= m. (y~'] CutPIDut.a meCUI. usa CutP)uuba Pl.ama 15,
~~43. 0.6 0.= 43 19.23 Chi g7 Fa4ILT C F R I T H i l D a r.~~
0.45 CralTHInP55' E*E850M1 1. 0.2 0.= 1 CLw!TMium usescapuu la.= 3.2 0.= 9 1.83 nittum vangum 2 0.4 0.= 2. 0.g9 kgrd) htlLa aDa*St 10 2.0 0.= 10 4.41 C: rantLT COLumur.LLipag agacHg5 Ont.sa 44 9.9 0.= 48 19.65 i Confoagargl5 AFmIPLICafa 9 3.0 0= T. 3.03 alTett.La L"maTa 6 l.2 0.= 5 2.lf dbb "~' raeILT ta5CIOLaRIIDAE i
~~'---_a rasCinLapla Littum 3. 0.6 0.= 3 1.34 =~~
f m a n ci er g.Lin a r j-- ,'-), F a u l t.T ma>ClmtLLa aPICIma 49 9.a n.= 3a. 10.45 . 4 pagtLT rita I C I n a r. 0.P9
~~"*" c a l.a T NOPung n%786:a num 2. 0.4 n.= 2.~~
ld t it=q5aLPle a f adF' u5t s 2. D.4 n.. 2. 0.F9 - ra#lLv ma%5aalpa6 wassau sses v a ht.I ST. $1.4 8.= 43 17.90 f881L1 08.1 v 5.1.1 l u a s Ot.tvrt.La 58 4 0.0 0.= 2 0.94 e e a -
l l i - Table B-2 (Cont .) .
~~~ "~~
CONeELL 8ETCALF E FDDT $919 SaSle = CUuTRUL kFPorf FOR Fm0RTM OUaATEM FLOGIDA Ponte CnspnpaTIUh OVFpaLL UENTUel CDemuelTT STRUCTUPE STUDI AT CNT5TAL RIVEN P0wtR PLauf
========mg=PER OF I40lvinuaLS.======= =======PFR SOUaPE atTEN====== ====urf utICnT==== ====0af WEICMT=====
N MEam Wa4GF Sin DEv 70 fab Ptam/m2 TOTab PEsp/m2 TAIOg Fau!LT m I550l ul0aF-el550!aa SP. 3. 0.6 0.= 1 1.34 raalLT TunnIDaE PipGOCTTuana PLICOsa 1. 0.2 4.= l. 0.45 FamILT VnLVaTELLloaE CThinos0nULLa stault I. 0.2 0.= 8. 0.4S , PHTLum aRTMAOPOpa Cha55 CausfaCFA 07.400 17.400 38.7800 4.3422 , SUncha55 CipalPtola remILT Raba43DaE RaLam45 SP. 3. 0.6 0.= 3 l.34 8U8CLa55 aaLaCOSTesta ORDER NTSIDaCF4 pa U480 SP. 2. 0.4 0.= 1. 0.S5 1 De0ER lamalpaCEa DO S u p0 RD F.R R040a0m0PMona UNIO. SP. 4 0.0 0.= 4 l.79 l OD ORDER 550P00s
>= Fau!LT amTNURIDat U4fD. SP. 3. 0.6 0.= 2 0.09 FaWILY EICuraLLaNIDaE UmtD. SP. 3 0.6 0.= 3 3.34 FaelLT SPMAEkOmaTIDaE Uulo. SP. 15. 3.0 0.= 15 4.11 OpnFa a=PalPoDa Fa4fLT 88PELISC30aC U419 SPP. 14 2.0 0.= lo. 4.09 FanILT asPITHOIDat U4to. SPP. 64 12.0 0.= 32. 13.52 FaulLT a0mloaE pulo. SPP. 20 4.0 0.= 9 3.39 FaulLT RATE 10at .
UNID. SPD. 2 0.4 0.= 2 0.09 , FAMILY CO*DPMilDaE U410 SPP. 32. 4.4 0.= 26 II.08 FanILT LIL)FPONGilCaE n=IO. sp. 1 0.2 0.= 1. 0.45 FaulLT P E Ll f lD a F. 443D. SP. 20, 4.0 0.= 17 7.18 , a OPDD M brCaPiipa F a m t l,I aL9H6tDaE ALPMEHS ammis.Lains 20 4.0 0.= 20 0.W4 . aLPutus ugitutoCMaF Lis 74 4.0 0.= le. 5.16 aLuntq% kow=an%8 25 5.0 4.= 24 10.63 SLPMENS SP. 2 8.4 0.. 2. 0.A9 j h ! i Uh ll lh Fa4ILv HIPP9hTTlhaF
~~#:PPn: TTs. ros.up aCa=Twa 55 II.o n.= iO. 13.30 V g (~d { ['y~~
~~LaTWFhTFS throwo= 2. 0.4 0.= 2 0.09 IMUM Donel43 19 3.6 0.= 14 0.05~~
Table B-2 (Cont .) CombtLL *tTCabt & sont 8919 anstm - Cngfant pl PeteT 848 FOURTM OuaPTEe VLuTunt PLoulos Peses.u CnwpppaTIoh outPALL C0844NITT STRUC ruht STupt af CNTsvaL MIVSR POeER PLANT
========uuPete OF INDIWI0 pat $======== =======Pp# Su nset upTEP====== ====WF.T WF.!GHT==== ====DWT WF,[GMf=====
Tagnu 4 pL4m 9 A>LF, 6tD DET mLampu2 TOTAL fnTAL PEAh/42 THom SP. 3 0.6 0.= 1. l.34 T0ZFuga CauoLI4145E 3 0.6 0.= 1 l.34 FaulLV mAJIDal LIMI484 hupIA 5 5.0 0.= 2 1.00
#FTOPw9puaPhl5 SP. 2 9.4 0.= 2. 0.89 Pt ble m'eflC A 2. 0.4 0.= 2 0.49 F44fL1 OGTelDat OCT* IDES SP. 2. 0.4 0.= 2 0.09 UGTRIDF.5 gaQUIFuSIS 4 0.0 0.= 4 3.19 fee?LT PAbuwlD4E PAGURUS SPP. 38 7.6 0.= l6. 6.7)
FantLv P4Lakm9mID4E P4LaF30 METES INTENNEDIUS 1. 0.2 0.= B. 0.45 PFalCListmFS 4=FmICAmuS 20 4.0 0.. 16 6.18 p4 PERICLleF4t$ LONCICA00aTUS 57 88.4 n.= e l. 88.35 I u%lo. SP. 8. 0.2 0.= 1. 0.45 b0 FAMILT PEmatI0aF 1 PEmat.US SP. 6 1.2 0.= 2. 0.04 03 Tp4CHTPEm4FUS SP. 2 0.4 v.= 2 0.89 l kJ FA4tLT Ple=0THERIDAE
P!491sA $P. 3. 0.6 0.. 2. 0.89 l FAMILT PORCELLA410aC PETROLI5 tut $ ang4TUS 3. 0.2 0.= 1. 0.45 l
~~l PFT40Ll5FHF5 SP. 284 42.8 0.= 754 95.70 FAMILV P90CESSIDat~~
~~AmsI0Esite St**ETPICUS IS. 3.6 0.= T. 3.05 F448L1 EawfulDag EupTPantPLu%~~
~~j DEPSE55US 100 20.0 0.= 91 40.05 { ], hFDPA40PE P4CKapul 8. 0.2 u.= 1. 4.45~~
~~# FOP 44APL TF.IANA 22. 4.4 0.= 36 6.99 msDragoPE SP. TA. 14.0 19.12~~
{2]Z' Paur>PrH5 MEWASTII 5. 0.2 0.= 0.= 42, 1 0.45 c3 P449PFU5 OCCIpFgTALIS 3 . 0.6 0.= 4 l.34 PAgorrus SP. 10 2.0 0.= lo. 4.47 U4ED. SP. W I. 16.6 0.= 79 34.33 SU8480Fm m4TAnflA (L_ ' Unio. SP. 2 U.4 0.= 2. 0.89 h31kb PMTLUM ECdignotwaaTa 10.456 2.097 4.0947 0.97s9 i i HNID. SP. 72. 14.4 0.= 52 21.48 , . PNVLH4 Cunan&TA L--- Z3 CLASS 45Clolacta 3.376 3.3978 0.2194 0.ATS . CZ,Ed33 9NIu. SP. b. l.0 0.* l. 3.12 C"-' CLASS n57FICninyts 5.939 8.184 1.0752 0.2150 {,}g) unin. sp. 6. l.2 0.= 1 l.30 . r,-- -=s L3
.. .. ~ . - = = - - . _ ..-===e
~~Table B-2 (Cont.)~~
$919 CDheLLL eFTratF & FNOT FOUET 88 Ouestra pa584 = COhfuob MFPONT FHR OgresLL rLOplUA pesWLR CtWPOW A114'N VE4?HN! = Cue 4043ff STRuffunt STUDV af CRISTAL hlvER PDDEA PLANT ........hppnpu DF SWOIV10tsaLs........ .......ps> senser. mL1gu...... ....urf WEICMT.... ... 0af wEIGNT.....
STO nEV TOTAL mLan/m2 TOT &L mLAN/m2 m # tan NauCL Tampe 397.40 232.297 42.459 93.7299 10.7453 TOTAL 2036 407.2 384.= left. H I 59 I OD L,2 e ee J\\ sh . uS JUb e W 5 e
I l l Table B-2 (Cont.) i left l Ob4mELL mETral.F s f.Dnf POUSTM Gesantin PEPUWT 70N nytpaLL Ba$le - UlSCMARGE FLDMIDS Ponte Cuppna4 Tine
~~vt4 TURI Criemug lT V ST8HETuht Stunt AT CaTAfsp, plvEm P0 men PLauf~~
========muertR Or l ab' t I nstaL5= **===== ====O47 WEIGHT ===== ======= pen sottanE mettp=***== ====mF.T WFICHT====
STO DET Tnfab mEAN#m2 TOTAL MFAN/m2 m PEAN *adGF Tanom - 115.790 16.543 36.5056 5.2858 Puttum PonIFE44 O. U.0 0.= 0 0.00 Umlo. SP. 0.372 0.053 0.8140 0.0863 PMTLU4 COFLENTEmaTA Cl. ASS agTHuZO4 0.30
~~3. 0.1 0.= 1 U4in. SP.~~
0.027 0.004 0.0972 0.0025 PMTLUM PLATTMELMANTHES 0.= 0 3.05 Uml0. SP. II. l.6 0.075 0.088 0.0530 0.0076 PnTLUM mEuERTINEA 6 2.24 UNIO. SP. 7 1.0 0.= 0.012 0.002 0.0804 0.0985 "4 PHTLUm SIPUgCULA i.. 0.= .. 2.Si
~~;, U iO. sP. iO.~~
~~3.0 0 0.440 0.0 2. 0.ii46~~
~~,TLU. 4,.ELlo.~~
~~n CLASS POLICMaFTA g,~~
FAMILT CaPITELL10at 29 80.80 CAPITELLA CAPITaT4 32. 4.6 0.= 23, 3.3 4.= 70 7.39 METFPO4ASTUS FILIFnnalS 37 13.02 nr.Oloma5TUS CALIFORNIENSIS 40. S.7 0.=
~~8. 0.8 0.= 1. 0.30 UN10 MP.~~
~~FAmlLY CIAm4TitLIDAE 3.4 21 0.64 TManTa SP. 24. 0.=~~
~~30. l.4 0.= 10 3.70 uutn. SP.~~
~~FAMILT EH41CipSE 5 2.48 2.3 0.= ( ]) mapPMTSA SagGUlmEA UNIO. SP. IS.~~
1. 0.8 0.= 3. 0.30 FA4tLV GLVCFWIDaE 1.4 T. 2.57 C- - GLTCE#4 kmERICA44 10. , 0.=
FAMILY ME5109tnat 1 0.1 0.= 1. 0.38 GTPfl5 m*EusPaLPs FantLY ma66.Lom,046 l.0 0.= 4 l.41 ((([h maGLLoma PETTIP0mF4E FaulLV M41.DaulDar 7.
12. 3.' O.= 10 3.73 4110 THEL,LA muCOSA h Faulby no.p e l p a E

3. 0.3 0.= l. 0.38 ,
Ct.uafumFuEls SP. 1.= Al. 22.40 = g gh LaFonFpp l5 (ULytel 158. 29.6 10 l.4 0.= 6 2.23 g' 3 wo ur.15 SuColhf a 0.= 2. 0.16 upatl5 SP. 2. 0.3 II. 1.6 U.= 6 2.30 h?b2d unin. SP. - t amit 1 OmH PM l tie r 0.4 0.= 1. 0.53
~~%.$3~~
[gi niopaiwa Curuta umuPMi % us Pui,se',a 3 4 0.6 8.= 1 l.13 3 FautLy nemlullna6 ([ M8PLO%CuhuPLDh ROHUSTHS 4. 0.6 0.= 4 l.51 19, 2.7 0.= IR. 6.75 a NAINF.HLIS hP. 8
es se a
~~3 8 9 0 e i~~
~~i B~~
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~~ea P.e C e~~
~~-.a .e%. e e .- J me . e e.~~
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e > t _J es 3s3 Ee 3 D O O O E um se s O o e e Q% .e (v) 9= h.0C
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e e 3 8> ce m au 3 O
.J O m Gn fe E > e m> e e ee 884 w 0 0W 8t ESe ee e e P 8't W @ sul
OA oft > O F 9 E ef't Mem mm 9 sul e e P rm me EPt es > @ M S P fe M @q seg m est m ao G 9 4h o e e o e o e e e * *

C ee e e o e o e e o e o e o e e e o e em 0 0 O e e ce m OO O O e

M O se e >O re M e e se M ee O 9 9 d'* M m em P 5 9> en se R 0 0 wt el 8 I
> 0 h d um 14 > e e e e o e e o e se Oa J. e o e o e o e e o e o e e e o e e o e o 3 = 4 & en dee en a= M se e e W ft am M CN P e O f% 884 e e er um as a= 9 ==
2 >J Z 9m om se C e M em a e as C ep' == E> ** 2 en) uf C 44 D eU S&> os = 3 6O3a CCe G B B B 9 0 9 9 0 0 9 0 0 0 8 0 0 0 0 0 0 0 I e 8 e 0 e 5 e e o e o e e e o e o e o e o e o e e o e e o e e e a e o J to 1Y d q4 g O O O& O C $C O e W en O OOO OO O O O OOOOS OO O O D O 6> an a
~~>E&4 6e Oe C&~~
e' & a s= a e ee^CO E 9 J&&a es e e J to E 9 W O set 9 se se m se se g est aut e e se dab o p en e em e O o es en e o se e se e en 9 4 4 e W3 & $ X e e e e o e o e e e o e e G e e e e e e e O a O eo O O M su se e O se eO se O e O O se e es O O O se m 3 ee e e e se se M y == in 3 e is, J BB 4 E
& C3 9 J> t aw e e & 8 e o e o e e o e o e *
s e e e o e o e o e o e e o e e e e o to e m emO en en to ee art > e ce sun M m re > e O w art P*

e == == se O M m um en p 44 0 3 e m en se se en art se se De De em S
~~3 8 5 O 40 ==~~
== E te i J e V e 3 4 > 3 ee ins W em e e tG e e to as e e go' C em ts E E g as u y C3 eJ B es Ina k 3 E>== e c y e s e We a *= se C e O 3 em y s=c==
Q oJ. ge e en er : F ** eC W &SeE e in3 Da O&W& a ab U en JC S e CC C en aeF em > Qe Q e & & es as e em se & tal C>> W Ce == e > & a = w c a s e' e n, a, e i 1 0, EeJJ O C ** en *Om
~~== &~~
~~UC laf U Ina e OeO er~~
*Q e W==tr.J O E * & E T W3 lol == 3 .a 3 3 ==
~~UC32 a .ea==. d . =D e= to m O J e t% e 6e to 88 a= 2~~
== v e 2 o' J e J **
M TmEmEDW ww=&w One Cd Je Opu; =mecmaem C4= 0 OS &=5 J F C F & > W9 C em 8* 2 te J ==CaQe4=O e WW X m C es se em sm == == =e'O=aaa 89 C J4 e2>J 3 ** F ** ** Gm se & *5D ekIF se C e6 2 e3 3 'a 1OJC=E e=W e>F
** 4 & tas to e#UI2 a2 O&JJ U G JB ee etal e ismso e J 3 & wt> *J WB 1eme aba&4 O ee O==ea& e4&totrOJ.3 WeC e ; e C U U e e C er to ** CC e&d> ef *3 & JJ e 7 s 7 T "a" V & &
2 C O F 4.8 OeeW= & & O O J J >as WJ u se U 1 M C = U *= *= > a e 3 e n * * * & S C O

F=
~~I e O & ** = == & T * & Cmoe4 == e4~~
~~ea & O e int t viJOes e>E m a e > == s e esas w> e z C n b es a2 > e= C v ==&&== W >~~
CO e O as se C J ier W 3= r 3Jw e U er a w J* Z U J UUU C ===== W ** as s = m J ee C z J= a J2 e V e is. O e e e= 8 Jp aw "a N W W se a 3 m > > E a= ei > e > N > e C z b > > == F *= > J k a= U > tr a e > s en e an a sa >dm a t- w3 2 e* ei
~~= e4= J e e e J J ** J .' J to J 2 J & &w am W5 te =J= tm = Jme4 C s J e e2 == == .J J J J W J U C J tr. ' > e J W W =J V g~~
i C m m = = sem = g = = = = = E b* r W S a 3 4 E 5 W E E W W W 5 S & e e 8= e e er e an e e e e e se e e e e M b ab ei e eb N E 3 W b b b b b tin he b E to b 3 en b e b to tem M pg **> Q Je e e E E M DJ y J t eo e zw v v p'J a s. > e, I I 4 I-B-85 a
E=mo ai ' 4 1 1 1
-
~~t , p l~~
~~4 OM 9 E eE G% s4~~
> a e3 62 e p > oa >e e I se ae E tas em U& e e
r E. as m I op b . O 3 ' E t
~~> to J 9~~
s Ee M i D O> l O eC e= b S> m 9 e l t e e t M 8 0M 9 E
~~9% >~~
Ga E Wt 3 as ce Ch e se & > ta; 3 aJ Be m 0 De p 0- 9O em E e> e as e O J e E > e N e e O e se e m Cm e o e ene 0 0 ml 881 @ e e e == e art em P em t t O B 4 0 43 en p= m > t art O aut O e s't an 9 f* tt == 8"e d'o e e e o e s'e e e e o e e o e e e o e e o Q 0 9 O m e O == m O == N ** * *
O # *
& O 9O se C O 9 O == 0 me en 6 9 to se I E 4 0 eS 4 9 E Em 9 .
2 == tC ta o e e e e e o e e e e e e e e e
~~> : 3 as m e e e e~~
e a e e em e e se se p M w #t sut er * == F e C ea % en em em en m f% e *e O em>I 3 - M ins ee Cb a t= s= a in" d Od
aO eb> = = = t 8 4 8 8 8 8 8 8 8 8 9 8 w3e2 C O as e 0 0 9 8 9 0 0 0 0 e e e e e o e o e e o e o. e e o Jh7W PC& *

e e e o C O O O O O O O O O O O O OO O CO O O C e U = 6 U tm > B
~~> 3 3e bm to C e. O&~~
E&3* 9 el O C S 9 Je&= d6 m m M @ ee em 4 O sa >= C0 W M em Sh as e e me as so O e9 o e e e e e e o e o e e o e e e e e e e e e en e t$ e G E O eo O > m a 2 2 ee O C O mO O e O se sat O we ce o O se F se d W 8 4
~~O a4 0 E I U C3 S l J> e e~~
bJ e 3 6 e e e e e e e e e o e e o e o m e e o e o e e o m M *= > am 9 at es s * == uPt e M eO s** e* == 8e *= t= 6 M m em se m el" M W 5 E M set em
==
T D E a C U e 3 e == et I C e= t= Im Im3 .3 3J e as as int e9 W le* e V. S e W Ina D as e u2 tm W kF e aO e e se O == G> 0 0 >ICW*ea W *- es e == 0 ee e b == ==
~~a F O OU e == inn e ZOM == las te y & ; == as &.~~
Cu U &= 3 6e as 3 se me se h w e3 ee e C ini le e as O ;m; J W **
~~^ .3 e sa& as sma& O as.asaa a y e .n; J EnB e y e. e lei J.~~
~~as a A aM e == e* *a =0 a e en e& V~~
~~4. 3 y~~
e se J v. e3 e O en w yn e. c64 J wp O R& e eCO epeC&O J O C C h c Of p rm>& se 1: 40 es e e. e e J eO4-&* 8-F E 1E eE == e == m W == & W fel W e: e ** a as 2 ee e= 3 W" s* O as y 3 == en an e s .3 O e em a to 3 u O a= ed a e ini e in o c e= a. O & ==
e w e x == 0*u- wa J e: U 3 e = a ma e e e e me e v e a J e e e sw *- E e a6 e=&-&-&ez J=&> ae=
O C W m J W e S C J E C U MO O e& E W Q U m eJWrwwwamma O - e a as a > a - - & v a e s ma - z e 4 : e =n& & M e s g J. m C & A W J - &3sv > e > ae: J 4 ee J2 V e at U T s == a e e. C e O C e == E e as e m *= eb W * * *
wt e2e e as ea e&e =a a w=em = *ur =T C = C == & a an em

e5W m3 O O O C& O O OU I E 4' &4 5 T J U U M C W9 E to U && C & ed a c J u == e a e a e 3e as ee Je me a= ==* e se == 4 M WD R>eme>=>m >= De NWhemp r>r>rewsmy>3OpJJ>&>- wJhe>*
g == F m3 e J B J r J t= eJ s a a em J e M C .3 E J 3 m3 3 J 3 J3J3J3 Jee32JZ>J == * ==J&J& e == a= = == a= no em s= I = == == = en == as y w se e&Cw s *= ea a a aa a e aw w s a a "a sc w a a e r es a e e e e e e se as e e as = 3e .a w e a w as e es we e as .. ts. Ib S Im ib b b Ram W WI U lam V 3 2 th Ob b tu. Ob h b Ob tm inn Im W as e ses axe a a e 8
~~,=0 ==> O e.3 e 3 pC O O O 1~~
4 aa > >Jn a aw e f5 e n. e= z. e u H i 1 I-B-86 D i fi. r ti a dg M MMu Tb _a
Table B-2 (Cont .) CummEl.L *FTCALF & #DPt 1910 mEPumf F04 FDUATM 00Apfft 04514 = DI5Cuas.E OfE8ALL VENTutt PLORIDA POWEN Coppon&fina CO*'U4ITT STRUCiunt STuDT AT C#fSTAL pivEn PowEp PLauf
========mumBER OF IMDivlbHAI.S. ====== =======Pt'8 SouseE *F19.u====== ==== PET utICHT==== ====0mf DEIGNT=====
N ptAN WANCE STD DEV TOTAL PEAN #82 TOTAL PEAN /m3 TAIOS PALAEco4ETES PUCIO 1 0.1 0.= 1 0.39 PERICLleLgES A*E#tCA4HS S. 0.7 0.= 3 l.2%
*FelCLlateES LONGICAUneTUS 14, 2.0 0.= 0 3.46 deID. SP. l. 0.5 0.= 1 0.30 FA4tLT plum 0TMtWIDAE PlumlIA SP. 4 0.6 0.* l. o.53 FaulL1 PenCELLA4IDAE PETaobl5fMrs SP. 4 v.6 0= 4 5.53 FAMILY PO*TuulDAE CALLINECTES SP. 3 1.1 0.= 6 2.27 U48D SP. 8. 0.8 0.= 1. 0.38 rAnlLv PauCESSIDAE ANSIDEATre SIM4ETAICUS ID. 1.4 0.= "s . 3.12 F148LY IANTHIGAE 4 EustPam0PEuS DEPHESSUS 9 l.3 0.= l.99 p4 g NEDPA40PE SP. 6 0.9 0.= 3 1.46 ng PAmoPEd5 OCCIDL4TALIS 12. l.7 0.= 7 2.75 g Heln. sP. 120. 17.5 0.= 94 35 88 (p
~~0.092 0.081 0.0300 0.0054~~
%J PMTLUM ECMIs00Esa474 UNID. SP. 5. 0.7 0.= 4 3.50 PNTLUS CMO90ATA 0.440 1.0616 0.1517 CLAS5 USTEICHTNTES 3.516 Um30. SP. 85. 2.8 0.= T. 2.48 D ,- >. ja oo - L% o =
w 4
i
~~l Table B-2 (Cont.)~~
~~x temetLL etf(ses 4 FPpy 8919 wFPOmf D e*w F00eTN ogspite RASte~~
Of 5CMa#Ct. OvEsaLL TEWTuot Floe:Da PomF8 Ca st Ps*= 4T II*

C0= set #1?f SteuCTyst sfuof af Cevstab witte pruta Pt.nef
========mUpute OF ImpIVIPqaL5==e**=== .......PFW Squamp p6These==ee emeekt{ kgjCyge e* ==**D87 ettCNT= ...
pamGr STD DE9 70 fab nFas/m2 TOTat pta##m2 Tatog . e utah inf ah - 1981 236.1 24.= 144 263.28 489.350 S8.623 243.1999 34.8289 4 Of 8 00 CD I E 9 (-9 E?'2J
~~>A ka & O IM u~~
i .
I l ! Table B-3. Diversity and evenness for each benthic and zooplankton s ta t io n l for 1979. m l ComeELL mETCabF 6 8.DDT I R6PONT FDR FLOW 894 POWCA C0appe4TIDS Cooses TT sfavCTuat sTUUT AT CarsTAL massa Potte Pham? elices:TT , tan ano eve ==cs8 cs: seroef DOTTom Cnet sampbg8 sfugf gram 3913 FIRST St& STER SECDhD SUARTEN TMIBO SUARTER STATIOE N E W E N E I ConTnDb 3.20 9.83 3.29 4.71 3.02 0.00 2 Comfa06 2.16 0.18 3.Sl 0.el 3.54 8.e3 3 C0= Taos 2.93 e.17 3.03 e.73 3.30 g.39 4 C0=Tn0L 3.20 0.79 1.04 0.75 3.e3 0.82 S ConfROL 2.92 9.46 3.58 e.16 3.76 0.05
;, 0. 466 CO.T. 3.62 . 75 3.,, . 76 3.9. .. 2 ;, i ...C a.C. 2.it . 65 2.9 . 7. 2.32 9.15 0.78 y3 2 otsCnanCE 3.02 0.00 2.S9 0.6e 2.24 3 015CuasGE 2.1% 0.14 2.69 0.68 2.84 0.10 4 DISC 44mCE 2.46 0.69 2.49 0.66 1.99 S.16 S DisCdanGC 2.39 e.64 2.69 0.12 8.9e S.??
~~6 DISCuapbt 2.69 e.66 2.93 0.13 2.19 0.70~~
? DISCMa8CC 2.48 0.73 2.89 0.14 2.?! 4.74 OVERALL DISCNARGE 3.88 8.69 3.06 0.65 2.03 8.69 FousT4 DU4RTER AmeWeb STATIOS N E N E I CouTAOL 3.43 9.83 3.77 9.00 2 Coatmob 3.3s 3.10 3.63 8.11 3 Costa 0b 3.11 e.76 3.13 e.le 4 C0efsoy 3,43 e.86 3.66 0.10 S CONTROL 3.46 0.77 3.02 0.15 ottaaLL Coettab 3.92 0.19 4.02 8.75 r ryg - -
D ;g r;s 1 1 DisCManCC 8.6S 4.52 2.83 0.66 i 2 Ol&Cua8CE 2.88 0.63 2.7e 0.65 q;, g;, . (;s j ,
~~,de L;~~
~~3 OISCuamGE 2.e6 0.10 3.26 0.18~~
% 4 DISCuamGC 2.32 0.62 2.58 8.62 1 Ol1CuawCC 3.65 0.16 2.60 9.68 6 OISCualGE 2.8% 0.68 3.09 0.67 . ? Os& CHANGE 3.70 0.50 2.96 0.66 OTEpaLL DISCMARCC 2.14 e.69 3.24 0.63
~~l t I i~~
. \ 'a Ob ,j g 1
~~i e em D as E e S W W~~
> to S 9 e m e fe 9 m ee e e e p= d a E 9 PeeeP P e p S e r= > d go 9= p eW9 e e e e e o e e e e o e e e E 3 3 8 OOOOO C OOOOOOO O e 3 O J > & E O s 9 m en e e Ps e m M co O se e e se 5 *= 6 e e em se M e a e e == e m e se W X$5 e o e e e e e e o e e e o e 3 Os G MMMmm m e M M M fu M se M 2 .
~~5 a O W & S~~
~~a W e e > e p m e ao M S *e E De $ emeee e e fo M S e m se e 3 OOeee meopp O~~
e m Os a e r= pope e eenseop e e e a 3 p a e r= e O ** an awe o e e o e e e e e e o e e e We e o e e o e e e o e e o e DOOcOOO O e O MJ W 3 9 O9009 O OOOOO90 e .3 3 OOOee O M ee w O e S> 3 es Oe O O a S e6 > e a 6 8e 8ese 8e D O e ane e M e e m a e m as e O M d Oaeeepp e en O e a w O e re *= re O e f* m e e r= c o e e e o eeeee ce p
~~es e m O O O~~
~~.3 km D u e UEe o e a e e e e e e e e e e e gg o e e e e e e o e e e e e e I~~
~~6 u E W 9 MMmmm m MMMMMmM m e mmmme e Mmmmmmm e l up~~
~~W e e e I heSe w WCW W E&S>~~
WCO O el s e5 3 3 a a O J P e he e e e e re e S emme94O e aus e me*=e m e e e ce e em #= W e 55 > 0 r= e e e e e peeeeee e se e e e e em me e edeFeee e e o e o e o e e e gyg e e e e o e e o e e o e e e a 3 am g ang g e o e o e 999OOOO O W *e W E 4 0 OOOO9 9 OOO99OO S as e O9000 O O Ee w 3 O u 9 O O
.O n I to to #e PmOme>> Pm th u ao De 9 fe m d O 9 9 e > e e me e e se T $ e e en O > > > e ce y e e e A D ao e 3 e M p m g= pm e e e e e se me e go g eeeee m e e * * * * *
e e et E E9 e o e * * * * * * *

e o e a3 9 e o e e * *

i y M s = 9 MmMMm m mMMMMMM m 3 3 mmmMm e **MmMem l e W m. o O e ,
~~C > e b o > Se a O w es W Q *e~~
.3 ab u u V W 3 3 5 e e
9 E E G S E S E to u > u O O W WWWWWWW W E WWWWWWW e o=
i u O uuuuuuu se O ueJuuuu gC 4JJJJ u aaaa9mm O JJJJJ u E 3 mE 33 m D sp OOOCD as * * * * * *e OcCCO *******
** W e 2 a er a el 3EEI E E E .3 3 E .3 2 1 3 1 2 3 E *1 CJ u O > em e. * * .s uvuuuuu J O e wwea a. >S > J uuvuvuv J - 2 ee eraer a c e md= e n en e e ae amaae a neeenen a H H OOOCO a > OcOOO s *====== m y a e uuuuu 5
W *S "0 0 0 000"a= W e uvuuu W OOOOOOc W C W to > > to e > le > e .* co m e e O m es a e e e > 0 es so n m e e O eMmeee> O I-B-90
w _h .J
@ !g ~ .M den c_-a 1 -7 @B e - .o a
M - e W se E a aE E e W W 3
> > 0 ee to ee e e a 0 ee & OO e O P > eb$ e * * * *
a e 3 0 ee e ee e s me as 3 e E J V b 50 O to S 0 ee e eC e B se e eo e ee e e W EEO e e o ee e 3 3 to e ee e ee e e 0 0
~~& se >~~
5 e 5 3 a a se ed tw
> W W to 3 ** a tie 0 eS e ee e 0 ee e ao M =0 > 0E 5 0 ee e ee w 0 e*
~~eM en W er W G e e e e o e d0 e e o e e % 3 D en a~~
& to J Int 3 0 ee e ee e J er 0 ee e ee e em W as a w e 3 0 th e O E S et O e.
S&> se 3 0 es e en ee e 3 0 as se e e se es em Oe a W O O ee e >e > e 0 e es e ea e as b.e b C U e U20 e o e e*
E9 e * * * *

3 er U a W 9 == O se se e se 8 pe se se en e em O b> > W W 9 0 W
Se 3Ee > W WCW W s W&B> e WOG O > Jab 3 m a 5 ee e e es e en to e W 9 ee e ee e W 9 ee W an em to e ee e ee e S ,= 0 em e m fe e e o e e o a C = aW9 e e o o e aW9 e se W E as e ee e ee e er 0 ee e ee e C ea w 3
& W W c3ma p p 7 e a bU to k 0 ee e ee e E 9 t M eG e es d"""* 3 se es 0 e3 e ee e > 0 %
ec8'e e ee e e e a se aE9 e o e * *
5E8 o e e e o e, p p a 9 = 0 ee e ee e 0 as se en en e e is e W b 0 0 ma C > e b A s
~~o > en O W W W e Q to se~~
=8 & u u e E E J E et S 3 e O dB C e "
~~5e 2 5 E n O .~~
O t.O OOWW** WW uu ** e - a 4 & JJ U ae e e CE} to JJ U sE O . e J as Oo ee 80 m E 5W J EE J B aa J EE J & U e O >> J UU J O >> J UU J O s=4 J oe Es e e et e so EW as en e e O
& > 00 s == a > OO a == a w A e UU W DO W e &U W eO W O > > > > > >
e e ee n O ee m O e Ee 90 ee n O ,ee m O l g 0 4 4 e I-B-91 e a e
Table B-4. Basic statistics on taxon abundance and total dry weights of zooplankton samples of 1979. CommELL erTCALF 6 Eont 8979 045te = CH#Teot prPoef rne SECOWO QUARTER EDOPLAGET09 PLO8tDa P0stM COMP 0paTInn DaT CnenUntTT STRUCTupt Stung af CPT5 Tab NIVEN Poeta PLANT
======== mum 0ER OF INDIVIOUALS**====*= =======PER CUnlC METER ===*== ***=ut? WEIGHT *=== ====08T utIGHT=====
TaIO4 N peau samCE STO DET TOTAL stag /m3 TOTAL ataN#43 PMT(Us Cotbrs*EmaTa Che55 utDn010a HwlD. 44TMOeEDUSat St. 2.3 0.= 9 4 17 um g o. 8.t PineEDU5aC too. 12.5 0.= 43. 10.0S 0#0ER st*Nn4HPWHWa b4to. SP. 30 3.2 0.= 10 3.54 PNTLUE ECTUPROCf4 CIPM04auTES Langst jne. 47.5 0.= 240 98.59 PNTLUM CMaETOGuafua SAGITTA SP. 333. 48.6 0.= 134 40.04 PMTLUm aumtbloa CLa5S POLTCMa*Ta 0.= 30.01 uml0. LaRVat 363. 45.4 120 PnTLug anLLUsCa Pa CLa5s elvaLyla u=In vrLL1GEp3 S3968. 6145.1 1830.= 13237 4163.6S 8
CLASS Castm6Poon 506.38 59 umgo, vtLLIGERS 6243. 702.9 241.= 5762. 3 PMTLua anTneopona CLas$ AR8CMmIpa bJ puntR acaplea Uh80 SP. 7 0.9 0.= 7 2.47 Class CausTICEa geln. Laeva 102. 22.0 0.= 80, 29.29 unto. SP. 9 5.1 0.= 9 3.30 susCtaS5 ses*CHIDP00a on0Ea CLaooCtea UNIO SP 95 6.9 0.= 31 13.03 C3 sUnCLASS COPtP5Da u4to. =auPLII 336 4 .0 0.= 06 33 bs_ 2 U48D SP 588 e {s.9 0.= 200 80.)4 3a Osors taLInns6a r- tantos aramill0aE 1995.= 32800. 10000.62 acanila fo*5a 72222. 9021.5 Q__- >- FamILt Co.eToop aGl oa t
'- . Crafunpar.es Co. esseTUS 10. l.2 0.= 10 3.54 FamILT Olar)quiust PstuoonsaPin=H% CO90NaTUS 134, 98.9 0.= 226 86.58 PaAILT P a p ar a s,a m i na r f PapaCabahu5 (pa53330STpl5 966S. IJoe.1 217 = leSS. 694.09 1965.04
(
'p Fastby PapaCaLamuS Paavus Pn= T e l.t.l p a t LapIDOLlus alpaalLIs 17856, 319, 2:44.S 39.9 123.= S100 0.= lit. 30.07 LaBIDUCepa sCufft 537 67.8 0.= 360 328.39 m
Wm t$ b .
Table B-4 (Cont.) CU44 ELL arTCALF & EDDT 1939
mErn4T Fne 3ECDeD OUseTEn 3881N - Coutsob FLOA30s Poete CopPopaTION Daf 100Pha4ETom ComucelTT STRUCTuot afuni af CAV5 Tab WivER PouER PLa4T

e ======== mum 8En OF INDIVIDUALS-======= *=== WET WEICMT==== ====DAT SEIGHT=====
=======PFA CHRIC *tTF#*****= stan/m3 a Peau m a n GF. STD DFV 70 fab nFausm3 TOTab TaE0s FaulLT TEeDalDag TEenRa Tuon!=aTa 35 4.4 0.= 26 9.29 FamILI TottamIDaE TURT4=us stTacagnaTUS 83. 30.4 0.= 46. 89.36 OpnF# CTCI,s*Polpa FaulLT HITHO4IDaE 699 87.4 30.= 173. S0.70 pante olTgoga SPPlDa PauPACTICO Um.a. SPP. 252. 31.S 0.= lit. 42.19 FaulLT 9 l.1 0.= 9 3.le aLTEuTwa SP FaalLT TaCMIDlIDat EuTFuPlea aCUTIFaogS 8083 1808.6 209.= 2350 633.67 FanILT TEGa5fluar.
uglD. $P 10 1.2 0.= 10 3.S4 supCha55 05Taa20na 9 3.10 U4ID. SPP. 9 1.1 0.= suBChaS5 ClealPenta uwlo, mauPhil 8540 192 S S3.= 340 Il6.e5 P4 unto CVPul$ 892. 24 0 0.= e6 29.18 i SUSCha55 altaCOSINaCa 080F4 IS"Popa 40 16.*S D8 usin. SP lle. 14.3 0.= 8 ORDER DECaron! ND Fa4ILY CnamGonIDaE 6.5 0.= 43 85.00 La umID z o r. a 52. FanILT SEmGtsflDag 16.67 LOCIFtp SP 72. 9.0 0.= 31 SumOnotw maTauffa 5019 627.4 142.= 1842 595.75 CamIDr.a= tota sue 0epe n st ef a=Ila 44 36 Pnaqght,amID 10Ea 190 14*0 0.= 130 BRaCHIuaam Zuta 82349 . 1518.6 473.= 4ulS. 1422 23 PNTLUM CHnanata Class LauvaCEa 24, 3.3 0.= 17, 6.39 unlO SP Class OSTEldNTHIES St. 6.4 0.= 26 9.03 U=lD EGG 5 96 0.= 40 16.09 untu v o,iD Lau.EariLE. so 9 Ig.0
.i 0.= 9 i ha m. _ -em - - - = - ,
~~-. __. -- -~ _ -. . . - . - . . . - - -. -- . . --- -. . - . .-~~
Table B-4 (Cont.) , CneetLL attCatr s rDDT 1979 SASIN = CimTDob #EPo#7 Fue SECOe9 98487t# FLO8tDA PDete COePORATION DAT ZOOPLawtTDu CDe#UetTT St#UCTumE STiH'T af CatsfaL MIWER Poeta Phat?
~~........su.meE.R.pga . .. . DF imotutocats........~~
~~tuage es,tga...... ....sgf uggcut.... ptan/sl~~
~~.. 0ST WEIGNT*.=..~~
TOTab staming TAIOe h MEAN DANCE STO DEW TOTAL 7074L 192759 24094.9 1885.. S7000 16353.46 0.000 0.000 9.7076 0.0905 h N 8 10 I F EJ El 22)
~~t'_) =~~
~~g_ 61 t-- i ) bL~~
~~<==~~
E9 t r U 9 1
l l Table B-4 (Cont.)
~
CDNhELL mETCaLF 6 EDDT 1979 I Gasta - Coutp0L MEPumf Fne SEC0e0 Quanten I goppbamaton FLORI0a poser COmPopailum NIGMT CommgalTT STRUCrumE stunt AT CRISTaL WivtR P0uta PLauf luolfl0UnLs...=....
~~======**NUm0ER..OF ..... PLp Cutic me.TER*===== ==** MET WEICMT- .. *.==0af WEICMT=**** -~~
TAIOm N Peau p a N Ct' STD DEV Totab mEam/m3 Totab sFam/N3 PMTLum COFLENTEmata CLa55 MfDengua unio, a=THO*EDUsat 15 4 0.= 35 32.37 UNIO. LEPfoaFOU54E #2 30 43 0.= Of. 20.99 Umin. SP. 33, 4.1 0.. 33 Bl.67 PMTLUm ECTOPanCTa CTPunmauTES Lauvat I2I. 15.1 0.= 07 38.30 PMTLUm CMaETochaTMa SAGITTA SP. 777 97.4 34.* 261 76.61 ( PMTLUm a m m tl. S p a ChaS5 Pos.TCMat ta u=ID. Lauvat 1069 133.6 0.= S07 199.34 raulLT SPIOulDaE UNIO. SP. 3. 0.1 0.= l. 0.35 PHTLum moLLU5ca P4 Cha55 nivacyla l unen vtLLIGERS 90000, 81260.0 3706.= 33897 9612.96 Class casTa8Poon 259.00 e,g umID. VELLIGFRS Self. 727.1 !?2.= 1063, uD PuTLum aWTMacPoon in (LaS$ C80$TaCEa Umle Lapva 323. 15.4 0.= 323 43.49 SUSCLASS C6PDPuos Unlo, kauphil 685 16.9 0.. 277 93.02 Umlp. SP 242, 30.3 0.= 872 62.J9 Onota raLamul6a FantLV aCaMTilDa0 acapita romsa 04746, 10593.3 4023.= 15010 3382.20 Family nlaPTuulpaR PSEUunotaPTuaus Coa 0maTUS 23259 2907.4 1420.= 3939 700.05 raulLv PanataLan30aE PanaCatanus C'455tp0STRES 6902 072 2400 03 201.- 8583 6940 . 416 2369,63 PaRaCabaut#5 Papvus 21442 . 60m.= 08 FAMILY Pnmitti, Inst Lantouce.wa alwantLIS 57]. 78.5 0.= 280 74.07 Lanipottpa Scnfil S6r. 20.9 0.* 46, 22.59 ramlLy TE=nalnat Ttroma TuuntmaTa 43 S.4 0.= 43 55.20 ramlLY fnefamioat . Tnafanus StT4CauDaTUS 75 9.4 0.. 44 17.10 OsoEn CTCLnPsilon UNID SPP 02. 10.3 0.. A7. 20.99 Fan!LI 037H5mtDar 130. 58.50 DIThoma SPP. 530, 66.3 0.= i t b
Table B-4 (Cont.) CuenELL et.TCaLF 6 F.DDT 3919
sattu = C04T90L utPONT FH4 SEC0e9 SunsTSR FLONIDA Pouts CupF0maTION mIGHT E00Phamatum cumMUNITT STaUCTuot stuDT af Catsfab alvER POWER PLa#T
= ==== = ===m. u.a == s.E ptsR.OF INDIVIDUAL CuntC 5======== ====wFT WFICMT===*
ut.TLR====== ===*DRT wtIC41===== TA30m a mEau pa=GF STD DEV Totab meanrR3 TOTab m F.a N #4 3 Osuta MaepaCTICnin6 U430 599 525 65.6 0.= 364 54.26 Fa#ILT IaCMIbflDaE 6806 950.0 277.= 1267 370.98 FUTEnPIma ACurlFROWS Fa 4ILY TIGastanat 16.26 HNjD SP. 46 S.0 0.= 46 090t9 gIU SP 15.20 u"H4$7PdLLotoa 43 S.4 0.= el. ButCtans CImm60Eola 1460 0.= 690. u u.nto sa, curais navvolt 304 103:S se S e.= i40 240:9e 46 06 SuPCLa5s maLacostaaC4 ONote CHuaCra 44. 15.51 HNIU SP 45. S.6 0.* ORDER MI5Ibacla 0.= $35. 49.16 SF 212. 34.0 C# DER umiufona. tso 0.= 69 26.02 Unio. SP 234. 29.3 ORDEs saPMIPnda 3. 8.06
~~3. 0.4 0.=~~
g enorm U%ID be.Cirup! SP FapILV CeauGuettat g u480 La#WA #1. S.4 0.= 43 15.20 D8 ran3Lt IEwGESTIDat LitCIFtp SP, 166 20.0 0.= 46, 20.12 i SunopOFk maTaufla q3 cab 10 ram Zuta 16006. 2110.5 238.= 4550 1682 29 CB 41585 Lauwat 34, 4.3 0.= 34 12!02 SUBORDfW af,Pf aNTla PHWCELLaptp ZQfa 156 j9 0.= 92 35 OS enaCH uman tota 34025. 3133l% 1 011.= 3300 . 022 62 PMTLum CMnovaTa CLa55 LarvacEa 949, 333.4 0.= 304 132.62 umID SP CLASS Osfe.IlMTMIES 125. 15.6 Unlu tGG5 UmlO LaevaE 169* 23.1 0.= 0.= Sj. 8 . l0 . CCF Lee) wm
~~'E2559 '~~
w T~ . y c_ _ U
e l e , f f e S On se SE e
~~DE 4% >~~
~~Pwk 8E M Se= E t= e o me 69 SW 9 4= OS DE ao O N 3 S P~~
~~>J =~~
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~~4 9 to FB e~~
~~t 9 em o GE O 9% O , te E~~
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~~. . c=:;~~
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~~@ j J~~
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~~& G$O m 94> ==~~
~~E O 9 et O tal 9E~~
~~se O eel em E == mes~~
~~> OS .ae:~~
~~C == es O O 0= J 3 e w ee C e S& enUW 9~~
~~=0 C ea D. o en a b an eos E bCES O24 0 =4h 0 W SWE~~
4 Y ee 9 UN On a m HEEe bini O bCe Ob P E & E so 0 es tas c a Ee JEb3 lal t J em S9 9 d d et aSE

2 O 38e @
~~E mean E8% 9 0 sa e E e V C3 e e J e= 0 m bV O e 1' 3 g~~
~~' S 9~~
~~4= 9 M S 9 R S~~
==
~~U @ es e= ee - 99 W D J E e E k O O u t= i I~~
^
e C 8 I EE 00 4t> l W3 at i em 1 l e EJ E l M ens O l'; .D ee eO es e q me+ en l g
]
l I-B-97 i e o
Table B-4 (Cont.) COm4LLL mETCaLF L Enni 1919 WFFDNT fnN SECONO QuapTEp OAStu = ComTROL FLnalDa punth CournpaTION OvenaLL ZOOPLANETum CommuelTV StepCTunt Stuns af C#TSTaL WIVEN Poute PLANT nP luolvipunt,5========
===*====mu.usta . ....=PFm CupIC nFTER====== ==== WET utlGMT===* ====08T WEICMT=====
h plan RamGE STD DEV TOTab mEaufn3 TOTAL mEau/m3 TAXON PMTLum COELENTfpaTa Class myouGZoa unio, a=TMnarDusst S3. 33 0.= 35 0 unsu. LaPTnatDusat 102 Il 4 0.* Og. . 23 99 6S
'5- ' ' '- '- *
o.0E. " IsaotOsun.a 10 0.6 0.= to. 2.50 UNID. SP. PMTLUm ECTOPSOCTa CIPM0mauTES Lantat 501. 38.3 0.= 240 62.01 PMILUm CuaETOCuafua 263. 60.42 SAGITTA SP. 1812. 69.5 0.= P=TLUa an=FLlos r"55 'Uki!"'t!',at 1432. 09.5 0.= S01 i45.00 FaAILI SPION10aE 0.25 4 ueIO. SP. 3. 0.1 0.* l. i PMTLUm DOLLUSCA to Class elvaLyla g umID. TELLICESS 144048. 9003.6 1930.= 12897 7102.55 Cha35 CaSTROP004 872.= 1763. 439.0S unID. VELLIGERS 52000. TSS.O PMTLua amTMenPope CLa5$ anaCngina ONDra scangua Upto, sr. 7 0.4 0.= 7 l.15 Class CouSTACta 19.1 0.= 121 34.02 um30 Lanyn 305. SP 9 0.6 0.= 9 2.25 3UnCLa55UNIp,smC410PODa au ONDFR ChaDOCFRA 9.46 CC) Umso. $P. SS. 3.4 0.= 37, SURCLa55 COP 9P00m fc U430 NauPLII 991. 59.4 0.= 271 70.S9 36 (_ UNIO SP 153. 47.1 0.* 200 fl. ORDFR cal INHIba ( }) FamILT afauflIDaE afanisa fossa 156960 9010.5 1395.= 32000. 1241.94
~~'~~~~
FaulLT ConfuovacInaE l b .* 0.= 10 2.50 CtNTROPaLF% Ct Ma*aTUS 0.6 ramILT usaPruelDaI PSF.UDnulaPTU"US C0ungaTUS 23993. 1499.6 0.= 3939 1549.60 FANILT PaPacatamIDat ( ) PanaCaLANUS CraSSSROSTRIS PapaCaLamuS Papvus 16647 ins 90 1940.4 2412.4 217.= 123.= 1955 6940 . S19.50 304).21 w
~~>3ED b~~
_m- - _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
Table B-4 (Co nt .) CoenELL *ETCALF & EDDT 1919 SaSin = C0eT90L MEPOAT FOR SEC080 OUssite EDopLaustog FLo#10a Puefe CudP084 TION OtisaLL CommueITT STRUCTupE sfung af CNT5 Tab m3VER POuta PLas?
=. =====musst.e ==.. or Impl930UaL5 .=pgs CualC .======
atTER***=== ***=st? htICHT=**= **==Def stICNT===== Talpe a mEam samGE STD DET 70 Tab stantal Totab mEasial ramILT POeTELI.IDat SS.7 210 51.9) LaelD9CtEn alSaSILIS 991. 704 0.* 0.= 360 St.6e LanIDOCLua SCOTil 44.0 raalLT TieuelDat 10, 0.= 43. 12.30 TLeoma funnimaTa 4.9 raulLv Tus t ag s p at. TDefamus AFTaCaunaTUS 350 9.9 0.= 46. 17.93 CaDie CTCLnpOIDa UNID FPP 82. S.8 0.= 02 20.50 FamILT OITM0910aE 16.0 59.56 OITwona SPr. 1229 0.= Ifl. cents waspaCTIColca Umln. $PP. 'T7 40.6 0.* 164 50.8S rantLY 0.= 9 2.25 aLTEutna SP 9 0.6 raaILY TaCMIDIIDaE 4HTEmptga acutIFR045 IS619. 976.2 209.* 2118 520.16 raeILT Tica5 float 3.5 46 18.60 U=IO. 5p 56 0.*
"" Ooote =0=5TwlELolna 43 2.7 0.= 43 10.75 UntD sP I sueCLs55 odTeaf004 9 0.6 0.* 9 2.25 Da umID SPP, 8 $UDCha65 CISMIPLDIA unto, hauvLil 3000. 108.0 0.= 690, 187.94 M3 u=In CfPul5 496. 38.0 0.* 140 30.83 MD SumCha55 *ILacostpaca OeCFR CU*4CLA 10.99 SP 45. 2.9 0.* 44 0800m U410lDaCl4 mT5 0.= 138. 30.26 UniD SP. 212. 17.0 080Lp 150IOua 22.34 valu. SP 340 21.0 0.= As.
ORDER 4 8 PM I P )8 4 U*ID SP 3. 0.2 0.= 3 0.1S OpDra DECIPo3I ramILV CR44G04tDaE 0.= 41 unto tota 52. 33 lo.e4 uitn. Lausa 43, 2*T 0.= 43 10.1S FaulLT Sruct%TIDaE 238 84.9 0.= 46 18.8% L 6CIFLP SF SuBoscoe antaufta tseIDLag Ent. a 28905. 1369.3 542.= 4550 1499.02
*T585 Lammat. 34.. 2.1 0.= I4 0.50 SU40a Dt v pfPfagfla v9aCELLa%3n Znta 154, 22.3 0.= $10 30 swaCngueam tot a 26334 164b.9 413.= 4885 Il21 7{8s PMTLUm two80afa CLa55 9,.. .... ... 3... l....S L.ae.l v.aC5 t a. .
~~pg gERA~~
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~~> $ 4W 3 em Op em Ca ma an. eoe O ** 4E Ne* @~~
Q kJ D se af ee a eeW 4 eS 8>Ce D e= 0 e em > =s R a enc m a C=e eea eeo J an3 W EUs e V se SOO WV 9= S DE24 b e; woe Ch S On 2 em 9 WCC Et JB 2m3 lal 9 J > SS See tf d em S4W eee 3 O 36e se d 3 3 me d Bee sees O as e a u 3D e J> 0 e kW 9 3 e a e eoe 9= 9 Ger G G B We een De to me U 3 1 E E C U I
. W ee ** 1-eed ( hedllp\.UMa -s a
~~g L.2.. , V t=W e 2 J K u d*3~~
~~U E~~
g? se eeC===C .S. g sa waar N o= eRssa W h= Q e tu es e e WJ B et 4 =s th - O e tR C se e3 eO e W G P4 De l l I-B-100 e
0 em n tu e DS 0% e WWJ 9E on FMJ ke e eas e EW G eS UE D ad De Om M Q 3 O A S tm J e O en
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~~pa a e vi es a C lel 8E e~~
~~> 0 tai se E so v3 M he CS Ja e 8 :esJ..~~
r : e rard - EM **uW e d C e9 m e=0 e s&> meg a _ , _ t> C a a O s as 0 deCu aus e as y em p - Ute De a es heB4 km W:W os .s.e Q E & B ** G bOC ES Jah3 WB J > ee 9 W at et AGE e WQ 34e e W antep 33w e O ea e a e U D3 e e JM t ft a bu e 3 6 m 0 o l p 9 ee 09 8 E @ p pa se 9 M
** 9 E
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~~@ e g m .a e e=& O M tS C se e no ew e~~
p I-B-101 : e 1
Table B-4 (Cont .) COE#CLL utTCaLF 6 fnDT 1919 NEPopf Fnu SECDe9 00ARTER 08385 = DISCNANCE FLupIDa Po*FA Csempos aT ION Daf 200PLamaTom CnenUmITT STpuCTUmL Siuoi af CaTSTAL WlVER POWER PLANT
~~========mu.nsEn . .==== OFPipINDIVIDUALS CuelC ========~~
mt7tp====== ==== WET utICHT=*=* ==**0AT = - a mEAm samGE STD DET TOTAL Plan /M3 70 fab uEICMT====3 mess /m Taxon PNTLUN CnFLEuTEmaTA . Class utnwotna S. uggu, amTunarousaE S. g.6 0.=. l 14 77 um!D. LEFTumkDusaE 12. v.0 0 52. 13 FMTLUm ECTOPAOCfa 143. 49.66 CTPnumauTEA LApfaE 209 26.8 0.= PNTLUM CNaETOGNATNA 65.4S 5aGIffa SP. 234, 29.5 0= $91. PMTLUM A m me.LI D A ChaSJ PnLTCMatta umgu. LanVat tel. 17.6 0.= 40 17.83 PMTLUm N0t.LHSCa Class sitabvta 1977.05 Uhip. WFLL]C(R$ jSu04. 1975.5 204 = 6502. P4 CLASS CasTanPona UNID. PffROPopa S. 0.6 0.= 5 l.77 g unto. VER.LIGERS 9734 1286.8 339.= 1982. 593.23 gg I PNTLum anTManP00s
>= CLast CausTACEA C3 Su8CLA55 COPtP0na 500 12.S 0.= 239 87.40 umIO. NauPLII 35 12.37 bJ Unto SP 35. 4.4 0..
080ER CALINOI6A FANILT ACaHTllDAE 50700 7341.5 130.= 38822. 19444.00 acAmila 10%%a FANILT OlaPfomgonE PSEupontapio=us CouomaTUS 342. 42.8 0.= 209 69.96 FAMILY PawsCatamtDat 234 41.= 165. 203.28 C3 Panacatamus Cya55IDOSTRIS 5012. PanaCabamHS PaWVuS 14001 Stae.09 23.= S225 1619.18 A FamIL POm[pLbluaE (- / LanluoCD.ua mina81LIS 110 l6.3 0= 97 2).29 LAnguoCess SCOTTl 404 35.0 0.= 40 19.34 (9 FAMILT TH#TamIDaE TURTamus SETaCAU0aTUS DenEn CVCLnPolpa
~~30. 3.1 0.= 28. 7.65 famILT H I T won g u a F.~~
08TMnma sPP 364 45.S 0.= 157 52.15 ORDER ManPaCTICUIDA 28.S 105 31.6S UNIO SPP. 372. 0.= fangLT fatngullpar L___>) EuTERPlea ACUT! FRONS 1364. 310.S 28.= 450. 132.23
~~'3 SUSCLAss ClaulPEnta 2002. 350.3 20.= 80s. 273.96~~
[7-s UNIu,nauPLII i 1 _1 L. ,) ch Ch tr " ene. . . . . . _ m-- ________
Table B-4 (Cont.) CDeaELL stTCatr & LDDT 1919 saste - OtsCuapCE >FPn4T Foo SEc0#0 Ogaatta FLONIOn Pt COMPOpation Dag EDOPLamaTDs CongUNITT STRUCTunt sfun'at uaf CmT5 fat psyta P0sts Plan? - i
.........u .. e..te or CUPIC .. pep ino Trovals.--=--..
nettp==.=== =***utt uttCuT=.** ... 081 witCu?***.* - Tasoa a ma a n pamLE Stp Otv TOTAL sta4/m3 TOTab stants) tulo CfPuls 44S. 38.8 0.= 315. 184.49 394CLa55I$nPopa
*ILacusTwaCA 08DFA se til. 83.9 0.* 96 33.37 cante u =,I o .n CaPOGI Supomoe m waTa=Tsa Cawlotas tora 5491 687.8 St.. 1355 423.15 $UBOspe u etPfagTIA PosCELLango torn 104 33.0 0.. 40 11.90 peatmTvete tuta Site. 644.3 195.= 911.
arcabuPa II. l.4 0.* 4, 2 S6 292l82 PMTLUM EChth00tamaTa unlp, estCMIOLaatsu LamT4 10 1.2 9.* 30 3.54 unID. OPHIUPLUTrus 2. 0.2 0.. 2. 0.T8 PMTLUm Cuonosta CLASS LaevaCEa 3.12 umID SP IS. 1.9 0.= le. pa Class 05ffidNT4IES 44. 0.* 87 g, o. U4luEGGS... La. S4 S.S.
~~.. 0.- 4... 6..0 24 8 >=~~
~~O 6e~~
~~......====m~~
-______m-
k Table B-4 (Cone,) T cometLL meTcapr a tout love
=Epuur rim stcomo evasten easis = sisCuanst FLomica romFM CoaPoseTID4 Cat griiPLamatog ConsuelTV STnUCluut STUDS af Catsfab PITER PS* 4 Pbte? * ********tumokA DF 140lvlOuaLS======== ====Def WEIGNT****, ******* Pts CupIC at. TEN ****** *****ET WilGWT**** -
57D DET TOTab stamin) Totab *tassa3 TAIOe N stam ma=CE TOTab 189495 14818.9 3935.= 41412, 15095.24 0.000 0.000 9.5e99 C.9637 8 Of I w O V LD ERS bsv tJ W o_.) . 69 cd W A,- sax, . c. r _ _- _.) l l 9
Table B-4 (Cont.) CDenELL mETCALP & EDOT 1979 WEPORT fna SgC0eg guanff# sasta = DiscuanGE FL0mlDa P0utu COAPneaTIOt alGMT 100Pta4ET04 CommuglTT STnUCTunt sfuor af Cptsfab WIVER P0sEm PLauf
= *= = = = = . *=N..u.m p E.R..O F INDIVIDUALS PFm CeselC ======== **TLp**==== ====ut? WEIGNT==== ****DAT WEIGNT**=** -
70faL stampm3 TOTab stam pa 3 a mEau PanGE STO DEV Tason PMTLum COELEmTtuata CLa5S plumotos 4.24 valo. LEPT 0 MEDUSAE 82. 4.5 0.= 12. PMTLUM ECTUPP4 acta 264 35.5 0.= 107 42.29 CTPMouaUTES LaptaE Pnthun Cu aETDr.m af w a 72.5 143. 49.96 SAGITTA SP. STT. 23.* Puttua n==ELIna Cha55 PobrCuaLTa 143 42.9 0.* 230 Gl.lf unto. LaNfaE PMTLug a0LLU5Ca CLa55 Rivacvla 3206.4 999T. 3054.65 unto VELLIGERS 26298. 1956.* CLa85 Casr=5Paon $2880. 1513.0 522.* 3332. 016.32 u=lu. vs.LLIGtus
]* PNTLug metamoroDa es g Cha55 Causfacta 20 3.5 0.= 20 9.90 vild Lanva SUSCLa55 COP *.Puu n 27.5 0.= lit 39.28 C) owlo, mauPLil 720 639 , 298.22 Ln unto. $P. 1258 $$7.3 0.*
080F4 CALamulna FaulLv a t a m ? I I D a F. 14200.6 2S48.* 23198. 4515.94 acaerla Tunsa illa 69 Faulci elapturinat 3540.92 P5EupoulaPlu*us CouOsaTUS 39308. 4922.6 1965.= 12520 Faults Pasarabanivat 1985 235.6 0.= 009, 254.99 PapacaLamus cwa 55IROSTRIS PanacaLamns papvus 18999 . 1499.9 T20.= 4S40. 1302.40 FantLT PO4TtLLIhat 100 13.5 0.* St. 20.00 LantpoCtwa almastLIS 23.20 LanlintCesa 5(t3171 329 36.3 0.= S2. Fa4ILT ftuGRIDAF 12. l.S 6.* 12, 4.24 TEpona TupptwaTa FamILv Tnsfaminat 40 6.0 0.* 44 16.97 instauus St.TaCauDaTUS C# Die CTCLnvotDa FaulLV ulTMuminaE 123.* 15.4 0.* S2. 22.02 olTMuus SPP On nF.e pa=PaCTICuIDa 22.99 um!D irP. 126 15.0 0.= S2. FanILT Eclim05n=luaE 29 3.6 0.= 29 10.25 altaust1ELLa Sr. FaulLI TaCMlullDaE 8139 142.4 J'
~~980 09.32 LuTEmpina aCullFR045~~
~~- - - mm e~~
Table B-4 (Cont.) ComeELL mFTCALF & EDDT 1979 sasis = OlsCManGE >FPoni # t54 SECOs0 Guapfen EUUPLamET0h FLUMIpa Puute CowP0aaftou mIGMT COmmuntTy STRuCrunt STu t af CRv5f4L NIVER poser PLauf amouv OuaL5=.......
~~==....===vmeta.er .===== PFm CuntC atTEp====== =====ET WEICNT**** = -~~
Tampg a stan pamGE STO DET TOTab Ptampm3 *=== DST wtlCNT====3 TOTab mEampm FAMILT TLCa5fluat unto sp SunCLa55 OITuatoga 996 124.5 0.= 207 17.17
~~untu SPF 30 4.0 0.= 26 9.56~~
$URCLa55 CIM*IFiola unID. mauPL33 3322 3 0.. el2 302.?e ugtn CvPwas 40 415 7 5 0.. 40 36.89 SunCLaSS mII aCO5TR ACa OwDeu CumaC* a u=ID. $P 303 12.9 0.* 44 80.00 ORDER mT5IDaCl4 UNID. SP. 328.. 41.0 0.* 183 45.64 ORDEs Isopooa u n t .a. 57 143. 37.9 0.= 40 17.70 ORDfM a*9MIPnDa Otto Sp 145 10.8 0.* 94 33.17 Daote otcleaul Sue 0NDe a matamTIa CautDiam Zuta 33618 1794.8 445.= 3A70 1990.47 Pd a1585 Lakvat 155 19.4 0.= 155 St.80 i Sutopos e RtPiamTIA es PonCELLamlu toEa 421 SI.6 0.. 373 2044,. 139.54 g
~~puacMYutan Zuta $341 . 64s.9 244.* $95.03~~
** PMTLum CMonnata C3 Class LapvaCEA cm umIo 57, eg. 6.0 0.= 48 16.97 CLa5S OSTLIENTMIES unto EGGS 02, 3 0.= $2 89 87 UNjD LANyaE S2 30.S 6 0.= 52. 80 30 Unto JuvEntLES SS.. 6.6 0.= SI. IO 74 0 0 Cc- ,,
t h5eJ . h h h?e) m b c: s3 e
Table B-4 ~(Cont.)- Cnnettb atTcaLF 6 EDuf sof. saSlu
UISCnamCt stroni 70s SECODO estattu E00fLa#ETom FL0eIDa Pouta Courosafloa alGuf C0880487T .T89 Civet STUDI af CatSTab pgeta POsta Phae 7
~~.. . or amonviovets.... ..un.e.c.e.Ptn ..~~
caste .stigs...... ....sgt ogICNT *.. 98f ptICmT* .. Tatog e agan pamCE STD DET TOTab staess3 Totab staufm3 - T.T. ....... ....... ....T.. ...... ........ ..... ... ....T. ...... 8 tas I w O N e 6 9 . . _ . - ~ - - - - - - - - - - - -
Table B-4 (Cont .) ComptLL etTCatr & EDet l9T9 utPnaf eue sECome OuteTra sesin . otsCanscr FLoalpa eneEn CosPosaTIOm OutpaLL ZOOPLamafum CDemuutTT steUCTumE STuoT af CRISTAL alvEn Poeta PLauf
........m.u.s s.t.e . .or,.s .P ru e : Csensenovaks...--.
ar.TEp..... . ---..Ef sticmT.... Def watc=1..... STD DET TOTab stessa) TOTAL agasps3 TaIOe a stas asuGF PMTLum inttgefrasta Class +:;onoloa 5 uutn. 4mfuosL00 sat 5 0.3 0.. l.25 umlu. LtyTaemsuusat 94 S.3 0.= 52. 13.68 PMILua ECTupenCT4 CTPunnanTrs Lapvat 493. 30.0 0.= 143. 44.02 PMTLum CuaETnceaTwa 198. SablTTa $P. 313. 50.0 0.. 60.50 P4TLue senEL30s Class POLTCuaETa 404 30.3 0.. ?)s. 58.85 ve10. Laevat PuTLue anLLusca Class esv4Lvga usso. vtLLICEpS 42095. 2430.9 204.. 9997 2576.41 bd CLa55 Ca5TeOPuaa 5 0.3 0.= 5 l.25 I unio. FTk80P004 3332 . 139.00 to umID. VLLLIGEnS 21844 1365.3 339..
' PuTLua asfuenpoca "" CLASS CdusfaCta C3 ud!J Lauva 28 1.0 0.. 20 1.00 Co SuBCha55 COPtesua 800 50.0 0.= 239 69 u=IO. haWFLII 1293 . 80.8 0.= 639 284.2e 44 unto, sv.
000F0 CaLat*lIDa FantLT ACastIIDaE 301Ts.1 730.= 3l822. 9545.20 aca*Tla tressa 512449 ramILY Ogapto-inst esEuonasarfu=us ComonaTUS 39723. 2402.7 0. 12529 3497.15
~~% Fam!LY PadaCaLattuaE pasaCaLamus CeasstpostpIS 3157 234.0 809 260 C:~~
~~ur - C)) panacaLagus PaavuS 260s6 1680.4 23..0~~
~~. 522S. 14%T.75 .94 (m~~
~~s g~~' 77 vanlLt gnuguLg,gnse LaelDUCena minaRILIS LaulunCtwa sCDIII 238 233, 14.9 at.6 0.= 0.= 52, S2. 28.05 20.70 ramIL T *.~~
~~ud B D a e. 32, 3.00 timous TuwnsmaTa 82. G.9 0.=~~
~~Fa88LI Tradi an g u st Towfahus SETacauDefus 15, 4.% 0.= 40 12.11~~
~~/C~. OpnE8 C T C Ln6"1 B a a~~
( _ 7', ram!LT ulTwovlDat ulTMQ44 SPF 497 39.4 0.e $57, 48.99 cCL'-0) 7 080FR >ARPaCTICOICa u=Ip. SPF. PCTIhosnsI0ag 295 80.6 0.. 105, 30.20 L "- a FA.8LT 0.= 29 7.25 mICauSLTELLS Sp. 29. l.S f:!qp t=> ds} C.__ _.4
~~C:7 })~~
6m Mi 9
Table B-4 (Cont.) Cut #tLL 4tTCaLt 4 EDDT 1979 Gaslu = DISCnARGE WFPOWT 908 SEC0e9 OUa87tR 100rbaution FLontDa Puuta CowPonATIon ovEnALL Com8UNITT STAUCiumL STUDI af Caf5 Tab alvEn PowEn PLAuf
~~......=..U..t. Or .oi.nouats....=..- -~~
Taio. . .i ;----" !!"l! " " ii- 52, 75 E' "*!!!!;;i- - ;3ttl "*!!;;;;- - FaWILT TACMIO11DAC LuTEWPlea aCuTIFNONS 250). IS6.4 28.= 430 109.97 FaeILY TD.ba573DAL umID. SP 996 62.) 0.. 207 83.40 SUSCLaSA OSTa,alnDa u io sP it. 2.. 0.. 2.. . 9, SU8CLA55 CipatPIDIA X:l;;E'Esil' SUBClaS5 maLaCO$fRACA
' lit: '11:: :: lit: 'll:11 DADER Cue aCr a U:;;,,5;,, iO3 .4 0.- 40 it.Si UNIO SP. 320 20.5 0.= 843 37.69 DaDE8 Iso $004 , ,Umsy;SPg 254 15.9 0.= 94 25.00 ,,,,,U;g;,gg, i45 9.i 0.= 9.. 24. 4 Pd SU8080s.e m&TaNTIa a CaaIDEa= 10Ea 1983S. 1895.9 04.= 3010 956.49 to avsgs Laevat 155 9.3 0.* 155 38.75 I SUSORDtw atPiamTIa F08CELLagtp tota 525 2 0 313. 92 30 Dd musCngumag 10La 19505 6)6 2 .0 0.g 195.. .= 2064 45) et C) mLGaLOPa ll. s 0.= 6 a 89 PNTLUM ECatm0DEmmata Uh!D. PuaCHIOLA# tan LantA 10 0.4 0.. 19. 2.50 UNID. UPNguPLUTEuS 2. 0.3 0.= 2. 0.50 PMTLUM CM0pDaTa Class LaevaCta ento sp 64 3.9 0.= 44 12.06 CLASS OSTEIdMTNlE8 UNIO EGC$ 826 1.9 0.= S2 14.44 unto Lanvat 104 4.6 0.= S2 81.01 UNIO Juvt4ILES St. 3.3 0.= St. 13.25
l Table B-4 (Cont .) l CumatLL maTCaLt & E00T 1919 ea51m = OISCM ARGS. MFPDHT Foo OECom0 OuseTER 100rLaMa10m FLOWIOa rumEn CouPomaTIon OVEpaLL ComeUuITT STsuCiuut afuut af CRISTab utvEm Poeta PLauf or sm03rl0UAL8=====*** *
..==....mu.es.t.a . . ..PLp CunIC METES === .. ....et? WEICNTeeee ****SST WESCafee=ee TaION a eram mange STO DET TOTab stamtm3 70 Tab oEna/m3 rapILV TacutOtIOat tuTEkP&4a aCUTIFM0mS 2$03 356.4 28.= 430 109.97 FamILT T6.sa5flest u=IO. SP 996 62.3 0.. 201 09.40 sunChass nsTeadnGa SURCLa55 umID. sev ClangPl0ta 18, 2.4 0.= 26, 6.97 UNIn. mauPLil 4 302.0 0.= 006 300.95 untD. CTPRIS 6))S.
3d 32.s 0.= 335 03.27 SUSCLASS m a t a( 05 f e a C'. DanER CuaaCFa SP 503, 6.4 0.= 40 14.58 ers OspEn umIOlDaCIA Unio Da0Ep s50000s sp. 328 20.5 0= 183 37.69 Da0La UmIO. SP amputeu5a 254 85.9 0.= 96 25.00 U410 5P 145. 9.8 0.= 96 24.44 Da0Es otCaPouI pa $Un0RDr u 44 TANT]a I Caul 0Eam Zeta 19835 1895.9 St.. 3070 956.49 D8
=t585 Lanvat RSS. 9.7 0= SSS. 38.75 SU80p0Eu mF.Pfamila l PO#CELLaNIU ZnE6 525 0 313. 92 to
~~p. musCnguaan tota 19505, e}o}.5 s .~~
~~0.g 195..~~
.= 2064 Se ,, NEGALOPa ti. a 0.= 6 45)s 09 C3 PMTLUm ECptm0DEmmata u410 PNaCHIOLattat LaRVs 10 f.6 0.= 10, 2.50 UNID. UPMIUPLuTEuS 2. 0.1 0.* 2. 0.50 PHYLUa Cwop0aTa CLa53 Lawwatta Uhto SP 63 3.9 0.* 44 12.06 CLa5S 051EldMTMlES uh3D ECCS 826 7.9 0.= St. 84 44 0 LanvaE 806 6.6 0.* S2. 87 08 e o JUvemILES St. 3.3 0.= St. 33 25 G2 '
EE@ F7 L_ C5dbb)1 , I t_m En - tr"
l l e s l l I e ' em e 95 9 OE 9% m P ue J OE ee 9pJ goe e ese e EW G GE H j DW **
*5 W .
~~R >J > O Be 9 U Ok ee H 00 e G S 9e M e 0 e 9 em O 45 e 0% G kW e~~
~~se e~~
* \ -
~~M g[f to e %D WJ O I &,# ee 3e O e $ e* D3 -~~
~~= u~~
=
~~wcm~~
=
~~J a > M9 W 99W ce B 9OO D O 96 e -~~
~~& 99O O ,~~
~~0Op e L a W .e .e nee.e I . SW E se~~
~~> Cs m J e.~~
~~O se es ce O kJ 3 es W 4e C g e se **UM >~~
*e Cd .=u e e a s= ees bCas 33g e JmOW EWS e e W es e Up om E M >a3e th emi O W3e CE m ,
~~S&WW e em Oc 5e Ja&D est t~~
~~=2 > &O se lef 4e aea e S O 384 e S me al B B et~~
~~O es e a o O CD 9 M Jos e N bu 9 3 0 e E B e~~
~~> 9 m f~~
G G E e i e h De m i I De @ me m B 3 J s e E to O O U V m o U C 6 m . E 4 U g na fE3 e oE sa
~~& mJ e A ** &~~
eO O u q =O e g S ee > I-B-111
Table B-4 (Cont.) es a 514 = Clo tikt*b ComeLLL mtfral.F & EDOT 5919 Stattilm= 1 WD Pulti e tim FOv0Tu egaaith . EsperLa t a fGo S LaeWlos Puut.m CDWrOkaTION
~~' Dal~~
~~CD44048 tf SThuC14ma; Stunt af CNf5fal. RIVfh PDelt PLANT~~
========husste of I mp s e local.s======== =======pge CupgC atTLh====== ==== SET WGs.esT==== ====D87 oglGasT=====
t a sis. W prag pagGL afu DET Totab ptsetn3 Totab 4Eampa3 Psertum Csit e t enve wata CLASS MttieJZua was4 angnuh*0ussE 6 0.7 e.= 6, 2.82 Om u6's 5 l PMere.'rhetes a umip. SP. 3). 5.6 9.= ll. 4.68 . PHTLum 4 5Cest.l.a g ni ng s os.slu. AP. 7 9.9 9.= 7 2.47 . g P.svLua CusefuC4atna g Sablita SP. 223. 27.6 e.= 80 37.35 , 03 e s* w it.u m aant.L:na a Cha%S PHL.tCnat ta
>d 0480 Latvar $13, 44.6 0.* 556 48.39 PJ p a y s.ue p0Lt asra rt.a 56 sil v a s.v l a dh a u. v e:8.I. lCt.h 4 4892. til.S SS.= 1S45 462.62 CLa55 sea.57pnenos uesp. t o.LI.l CEW S lete. 288.9 7.= 589 8S7.19 Pnte.um suTwanPona CI.a5% Caus to cr.a 54'mCha$s re s> F roo n .. ualu. haovt:5 600 75.0 32.= 102. 63.68 '7d> Dutit R r a L A.Hilisa e as I t.1 aCase r s loa n.
L- aran 184 l ee.5 4 23315 *2928.9 150.= S438. 1152.20 t a m ts.Y Ce = Tuprac t ri4 E , CLutweera6e s Ct . nae 4TUS 425. 53.1 S.= 156 S2.40 raetLY nl a yteea g ua s. kj FapILv ysvuutatil a vinau% Cnaequatus p*Macaba=trat. 1550 393.4 42.= 448. 138.60 i O pawsCat.*.am Cua55ta05?Nis dele. %S9.8 IST.* 816 221.00 i P ah aCat.a.a e5 Paw vies 90. al.) 0.= 90 3d.82
~~f3'8)~~
L ., _ ; Laats'tCtwa pihahlt.59 4.ar t en.Ce da sC.si t t St. Sv. 6.4 4.9 8.= 0.= St. 39. 18.8) 13.39 - CQ famILV Te.* sin t pae da f e asem a 1..=r e sent a 2247 Juu.9 69.= 490 855.88 Q3 131e 6.* 8e C GCt .IPs.t pa *
~
~~t ahl t.1 CatW IC a. Ipab; C.. ca...s s,. .., F J~~
~~a ali. u i t.*, . s u a e~~
.. ... .. 4.ls .. l i a. . . spp. laws. 2s7.3 en.. ele. 254.e3 u*= ns vaCr rnana , , . . . . s. ,1,. .9.. ... 463 S,.52 .
Table B-4 (Cont.) 1979 a s l ee. C'er t S'is. trow ke.t.f. P E10 a t.> 4 D ettet FOUpfes Oga>TFP st af f r*4 k 6.Pr*61 FHM I FI.tep lD a l en.6 m Caer Pf tw a T If ete par s eniPLae.n Tee s C'i> =it u l l t STo ut teswt suunt af rNv5 tat elv6.> Po.te PLagg
.....-.. hump 6p ear l etil v i sus a l.5........ .......P6h Cuelt M6TpM= --.- ....uET WEIGNT.e.= e ..QR$ WElGMT...e.
4 st aa pamC# sits DF W TOTab **.a # # m 3 Tofab 8Faktu3 tanum D amfl.T PFLTlHIl446 a LTt.'l l ee g .il* , A. 9.7 0.* 6 2.82 D on ll.V I n Cw1 ul 8 u86: 6 'TCPP R Na ACelllF>nWM 949 44.5 0.= 02. 12.5A F a r l s,'Y T68.a.%(lesa6 es=to sp. 24, 3.o 0.= 13. S.50 SUMCl a55 Cipwlp6 H e a eve lis. kaups.g l $276 659.5 91 = 1403 412.98 uwin, Crewss leg. 44.4 0.- 7e. 23.7e Sues t e.a 5 % *abacustuara t'a pp te S noPrvi. g d'e l u. SP. 189 14.9 0.= 29 18.03 g gg LiW D8.N a
~~PM I P'lu s u=to. SP. 77 3.4 0.- 27 9.55 g~~
~~rino6.u t, Capena~~
- Sunnwot.u matamfla Is2 65.38 t.s Castpeng toe a ele. 52 3 0..
SU P om p6' .e #6PfamTIa nw&C4towag 2064 13. l.6 0.= I I. 4.40 Puttuo coeuruaTa CLa%A a5C44f att a 30 34.06 efh t 9 bap v at. Sh. 30.5 0.= U In. SP. I3. l.5 0.. I3 4.60 Class L a w w a Ce.a
'8 M i ss. SP. INT. 23.a 4.= 18, 74.08 C 4.a 55 'IS Fr ICMT ee v $ g 4*s t s. t r.r;s 4, g.T g.. 6, 2.32 D
3
~~'D llhhk N !iu dmJJu s~~
~~t Table B-4 (Cont.) (.** ist,~~
.Si.. c.. r6. . t.i. =rreas,.r s roi , ..en= rne rovera ova tre . r i o.... i .
i, ... .. . i . rue s un v... . nwranatia= oar . rep eer.o rg stoe'C gt ht sitetet af C&TST6L bitre Put't Plast , < ........ ..e.. or innevenu a.s........
~~.......p,. rienic arte.w.....- .....c? wesc v.... .... , csseis..... '~~
74EtP. # Pe th FA GE SIO DET TOTab mEause3 Tofet stanssel l etT 4 . Sla l % 7 42h9.6 1996.= 19414 20e#4.11 0.999 0.094 0.1985 0.0339 4 Os I w 9=. U
~~'E.') %--J i~~
N GEE) - a@ c=a 3 e Eso W 3 A d f 4 t
Table B-4 (Cont.)
=.
pass.4= Co.e1 > tL r.us.'ve LL er tCai r 6 6pnf 1979 ,,
.s t a T g se == 3 p t PfewT Frie FOURTOS OUantre rennes.aantip. 98ewlUa Fu=>k One pow af g rue alGast .
~~(.erusatitif STN0eC4Hke Stout af CRIStab Niel.# P8fe'st PLa97~~
=== =====num eet p or t an t v itevaLs======== =====.=rth c'In t C p t.T EN = = = = = = == ==wD f af t. I GM f ==== =*==Dilf WEIGNT=====
taan, m 46. a n p a wce. syls op.y gnf at, mea g/ ell TUTab afa##p3 Fw y t.gs ,:C teepw. s 14 s*fpwee9aeets.g La6 tae 24 B.O ts . = 24 g.4e t*st y Lang Cas a *.T 9e;= a t .8 4
. int.l T r a sp. e jp. 19.e 24.= 347 St.44 e*ee V LeJ 4 ase.st 4,8 t.4 Chass yni. y Cpw i n uv i a'. I.ad f at. 500 62.5 27.= 101 30.23 Pu f f.u n mos.t.u st e g (LAA% eelWaLvga g H s t es. W e 8.8.t'.F 45 J759 3Jg.9 u0.= 750 246.75 g (s.ab5 Ga8 f dHe"Haa is I tp. W P t.I. g r.p it s glet, 224.9 47,= 403. 336.72 LII pae t hu ei a P Towe erut.a Cl.a%5 Cen%Farom .%U pC L a 5 % CHP* Paln a sue l o, as a. ort.I t 454 56.2 43= 97 30.44 9 pad G C al.a *f.s t b a t au g t,v acase r t s na6 tr aie t t a t.eeia 73967 9245.9 535n.= 13311. 2997.88 >aAtet e repTw ep se; nae.
Co .o rwny m e.6 % C6 w a = a t er.s 1477 209.6 nl.= 488 134.65 y a e II.T t' l 48's .s* I n s t p%tutwee,g a p f te ele % Cftpfjed a T et % jn98. 448.4 394 = 695 155.32 y p ei g g,( eaaw ag a g,ag g pag Pa'eaCat.a s*es ru ss% Passt& I S
7 9 9.

1u99.9 da).- 1974 463.50 rae s 31,f so o.* T e e.a.I b a s s.a a t e><n's ee s. f Co l t i 44 4. es 0.= 27 82.50 psalLt rt en I t.a *' q t e wrsw a temas.eata m9%9 1889.9 444.= 2456 632.05 ,
, ,.e e ., e, D ] ,] .. , C...es.o . . . . a D D ae t s.: s:owyrae tnes 0 .
~~y(;ppj, b Cece vC4.us sp. 24 2.* O.= 23 8.13 . d~~
~~e a a t e.y .e s f =.si. t oir -~~
~~.e g s .e ..i a es . #45n. Jul.2 187.= si t t . 165.42 06new r.g. g s.n g s. a e a= e s.~~
~~c' .t o. s .. g .e a e~~
.#.. i n .p. #7 3.4 p= 27 9.55 n .e e aav> ss e o f ..t eia se a t s. ,e s' . l'He. e u 4p u.= l 94 43.47 .
~~s a = 3 s. g e e. .e. i es n g I a.a o 8.""*. t =~~
~~e ' h * * *.~~
- F14 99.4 2%.= 349 58.22 e a t i e.t t% : ele e it.as . n r. 6 p e i. e e rsi t i p an-,:; she. 38 0 H.= 27 40.36 ..se re a .3 e ;e ea c g.g 's . a n , is r. 74 3.0 0.= 24 8.49
Table B-4 (Cont .) a s i ... c... ..n. es....Li,.rtrai.r s ui. 8919 _ hl a g s he. 3 >>.Puu t f ans FfppetM OUs#TER Untetaget fu
~~6 OfewIua pnet u CnupneaTIf.af NIGeef .~~
~~rown.s.s t ry stwe.(rpe, Stout si C#Vbtab ktvrw punte pgass? ,~~
........ seg ne,se stF I nn t y t trJ a t.S........ .......pe;s (qhgc a p t e.u.....= ....mt.T WEIGNl.... =*.*047 DF.IGMT.**.= ,
ra sse e , eean p alace. 51D PEV fnt ag. s t a's / m 3 TitTAL atausm3 sospChasa (tww 3p e.g a uatu nanebst ag26 eSt.) 166.. tall. 437.03 si s t se. L y n n. g .. 3%g, 44.9 n.. ggf. 45.08 ht=**f ba sh W al.aCo.4 8 84 af e f H. :sb W Cepeaf F a Wiln. 69 91 I.9 4.. Si. la.57 88 4pe d "V50ef8Coe HetQ. Sp. a ts . S.D 0.. 21 9.99 DeoF* I S* *PH a op;a t o. 5 e' . 136 42.0 c.= 90 30.25 flN PD m adpig g p ggg g 3
' Hip, sp. #I* I*8 8.= 27 9.SS tag n tpe.w PrCapopa l 6#*lbf %e.4e;6 5 711:a6 w I.itC IFD at P.p
II* 1.6 0.* 13. 4.a0 w siinnw n Fit wef4a33a e Caegpra% toe a A74 4u.5 n.. gn6 30.69 sein nunt u set P T s.s g g a r w a cu s'sw a n. An* a Sg. 7.A 0.= 25 80.98 s.ee r tu. rtee g es st e eew a ra
*I410. seem g.=ye.UTt.if S 74 3.0 0.= 24 B.49 t pit.ne Ceetwuata ri au est'IPs act a n*so ea.sysF 11 4.6 0.= 74 9.#5 s,ser v a(D a cg Cha%% . . . . . . . sp. .... ...a 0.. ,,. 24.9.
t > - GED E59 4-J e i C' J_ W.e-d'. . . g
~~-_ - -. . . .- _ . . . ... .-. . . . . .- _ _ - - . . . . . - . . -_ _., .. -- ~ _ . - . . - . .- ,~~
~~1 i 4 2 Table B-4 (Cont.) i~~
. f 4 .as:4 ca.~ e .. to ...Li. = rcas.r t. epov s.t. ,
rnweTu evneTra s n ai s.. .. : i.e. . r e i = f.oeis Lana tries # Lesiegna 6 set 4 Cnne rnp 4 T I sses alGast . cnetaes a t iv H usst reet. s g utet e r t'atSf at ptven rose.4 PLamT . ; L
........misget u ese Iupge3004Ls........ l 3 .......wp a cosm ic me.tta...... ....eET WrICHT..*= ...*Def WEICuf... .
] gasaw a maan manGC STO Dtf Tejfab stampm3 Totab pgampm3 4
~~.....L .. 4.. ...... ...... ...... ....... ..... ..... ...... ...... .~~
~~I Os i i N~~
~~'mO~~
'l ' ; i I a t l l l I
Table B-4 (Cont.)
i. .,rCaLe 6 e .ees v iet, re.,.

s. a s i .e. roe e s..es. plPANI Fees F00mfse Ouaatte sT a lles e. t 4 L.eM lba P'Im6 W CD4pelm a Tlean OT t r alt. ..
~~e en.F'#.8 es: ist. Cee.e*se.s t y $1kseCleert GTeHsf at CPT57al > 3 er.e poet a phant~~
........sepees.t se s er l eefe l v 3 feH A L& =...+==. .......pt-ce Ceed l C #Diese... ** ....ett estices?.... ....Def WEIGett.****
To:T A L sta##m3 tofab stepsma an t.6 64 wa=CD STil D *. T T a nn.# e.es t g.se y Cup g,a seTp 6 ai n Cl. ass es g s..a stese 4 0.4 0.. 6 1.50 es e l o. s ee f.o.**.u ess aE elus** se alPseu.a J6 ehe4 4 lsG I el. bP. IJ. 4.e 0.. t3 3.25 Whil.pg a$re.e Lee B 4 the % 7 W.4 8.= 1 l.75 gu a.e. %>. p.g 6 ettLesg *CrnPuoCTa CIPsens la.j f s'$ t.au Wap: 24 3.5 0.. 74 6.00 3 00 v.e y t,se
~~Cu at fe*r.P a T.s a 4~~
>. sar.lTT4 sr. nS9 53.1 0.. 107 40.0S w # p se t te.d 4 a = 6 t. t .3 a CLas.% PubVC.se.f a 1%4 39.78 ene g rp. Laesat m13. 4 4.e. 0..
~~PwThes~~
e el.I..e5C a C t

M. *.t v a e.v g a ite). 47$.7 3S.= 1545. 344.tS ep i g n. ve t.e.g e:6 p s Co.*55 rastenrona 3441 2#7.9 1.. Sl9. 333.18 h e t.s. vs.t.h tCo ws
...e. A ., es.e .e.e .. a re.a ss cue *r.T ae's a g.pers.a s tiev.o .a searn, n a..sgsg g uSees hS.4 32.. 1P2. 49.7S CD tour s.p c a s.a.an g e. a s a g g e.f me erf liesse as ase g g e a w sa 98947. Aquj.9 750.. 83398. 4036.02 g -.
tas50, g , q r . er an s has re a rens.a... s Co . es..a t us 247 333.s 0.. 488. 177.57 C3 os avi.o se.u C- e a e t e,v 196.06 L._ -- 3 S Cours.s a tus %#ss. 347.4 44.. 495. , e u e e.r9y u.e..e.p as sa a v e .".."g .e a s r as.a c a ars e......:. ra m e s musf u ls 184#P. u se.es Iu?.. 3474 449.51 C- pararag,h e e , p.wv es e. S.h o.. 90 24.50 O9 s a e s.n p re t t e s. i.nse is.iS cS = e.. .s i es. . a . . a .e i s. . si. ..., ... a.. Si. e .- .. i .e. e. . , . ..e .e r i ei. e.. iv. ia.es cMrs: e a . , e. , e e . . . e e...
~~,asa. . , ee . . .~~
~~g==> T. . . . s .. ...... ,,,s.. , .s e. . a .e . .~~
~~.....s.. e p e ., .e-. e ..r e a- s e.g : e.or ,esua.~~
~~r+ vea.:- .*. pg. 3.m o.. 73. S.no~~
. .. e s v . . e r .. es e, e l e .*. e .e se r. 414w. PSw.) 46.. e44. 310.07 - . _ _ - - -
~~Table B-4 (Cont.) rw et t.l. *p'TCat,9 & e,ppy 1979~~
~~.eadla= C t h818'e 't. s~~
pf*> T e sse, Ffpsefse Outettp A l a t t eee. 3 OV E A s t I. .
p' Naps.a* 4 in . t 8.sta l b a P'let # ru'Pnmafl0N res te..sie t tu sint*C l um. 5this t af Cer t s taL P t ve's l'elet R Pt,agt
= = = = = == = = U m ese.et tsF l eap t v l bstal 5======== ., . . = =. . . P t W CuMIC d6.TtN====== ==== WET WEICMT==== ====nef utIGNT*==== .* .st a se P a aer.E 570 IJET Telf ab est a p /m 3 70 fab stental t e Je.
punty rat.it selua 6 auls.f r a t. le: g ssp r. es 19 sr. 71 l.1 0.= 27 4.1% n= t'* w seappaCrettigna es t. l et. Sep. 191 et.7 0.= 163. 49.45 tantLv e, rem. i p6 u l i v a t. Loor.IP.*la %p. 1177 Ill.l 7.= 259 64.7% F a.4 B l.3 Pt I.T f ut lust s e.T*.b f M e sw. 4 0.4 0.= 4 1.50 eaglLv T acnin g tunt. g t uT*.esytes acollrwrip% 917 Sn.4 0= 127, 37.59
~~, ta4ILv T Lr.a s t g ust g~~
~~voto. Mr. 74 B.S 0.= 83. 4.12 i sismCt a55 *s%T w a Coe n~~
~~24. 1,5 4= 24 b.00 etNIU. $PW.~~
50'etL a n. Cgewin pla e d'I t n. aansyLi t la lq7. #st.4 98.= 1653. 440.35 Unlu. CIPwls S$4 34.6 a.= 887 36.35 sis *Csa55 *at.aC9518 48 a ow a.. w runact s 13.32 Umlu. Sp. 63. 3.9 0.= 93. N he.it evstpas 6 4 - UetH. %P. 40 2.5 0.= 27 7.29 9es.s e 3 sopspe a Hal o. sea. 4%S. 29.4 0.= ##. 2h.09 i esse.e w app.g g y.pe 4
*a' f 9 SP. St. 3.4 U.= 27 9.22 s ew e.e's e** C a re*ssa ta elt.t %6. tic.6 'e l t e,a p
~~3.45 8,dC I F6 W b t' . 83. e.G 0.= II.~~
Sis %stwt.* se seaf a aria p.= 842 St.25 Capga.ag is.._ a 147, 46.4 g - ' 51.4s h8 o 8W Wer17
.. a re. . ... . ,,a t .. 's tI ... 4.4 ,,.= ,$. ..,9 'o 3 < o D 1- .a >1 u! ~
~~J g L gj tj ,f .f3 J.u e.n.. . . . i .~~
e. s i,u. eC p.e s *s. c'e*+s t "pe.u l t OS J4 3.% 0.* 74. 4.00 shus.h t'w.e= 9 al a Ct.a s e. m*.r e n t at t a es, g e. a.n e. v a. 171 T.? n.. 3 es . 32.39

89. es . es 0.. 13 3.7%
~~.s . e .s. s .> .~~
~~s s.s.ss e. awe are a a e e. .w . tow. 49.9 p= T es . 23.74 r a a v, a s:, e~~
~~e r n e .e s .~~
~~%. en . 4 9.= 4 l.50 eal" **d~~
Table B-4 (Cont.) e s .s g . r* HoIN'90. CU4hD L.L ELTrOl8 & LMDI $979 s t a t s t'.. t k r P's# 7 f **m Fftssetse evastes stars.s o sit e e Lnewspa smes.e coopposeaf tfee evenaLL . reen teen I I T SThettup, 51ubt af CWisf aL *t VLp Pont e Phaef
........mempte se tenIvibwass=....... . .......pt.s c'en t e mitta...... ....eET wtIGNT***. ***.tet WElset..... ,
gasos as m6 44 p a mGt. Sto OLv Tufth DEsesp3 70 Tab attese) TesTAL leb8Al. tv)63.0 1954.. Fils?. S3%7.98 e.000 0.004 9 g'ae e.0 344 , L P4 e a tal 8
~~@2)~~
~~F#D 1~~
~~a-@~~
o l h ' w F ^
~~i. .~~
) i er 'I
l Table B-4 (Cont.) ass == re'aTWJt. CunetLL se:TCaLe & Lunt 4919 ' Stallsw= J ht Puw t f ue FOUGtM StfasttR gtw6P6.ame tue D Lo# 5 Da Freut W C0hPupaTlUn daw .. Cesamu'll f f 31MHCiumt h itsp f af C#fMiaL alvkn Poeta PLauf
========eumsta nF t m p I T I DG al.5======== =====.= Pop CongC no.i t's = = == = = ====ur.T WEICAT**== ====Det etIGuT=====
sensus a haan m a h gg- $70 ggy jyfag pp aag sp 3 10 Tab acampel 6 ed g Lled (ei n t,Tf56;.s 4 Im a sag 4tra &*. 14 9.3 0.= 26 St.25 pu t bi 4 age.e b t s.4 CLa%5 F8sbfCMapta . l'u l se, s.ais t at. Im4 20.5 4.= 48 17.Sf te s i d. Sr. St. 4.4 0.= St. Is.e3 PuvLue soLt.usca Class navnLuga e4 esclu. ve.LLIG6:ms 1994 8Do.t al.= 505 855.45 8 Cl. ass s;a%f.soviaea t2 sa gu. W684.IGFm3 579 47.4 0.= 139 57.89 I N PesTLue awfue Opinia N CL455 Cau4Tacta FuPCL455 COP
Pens 4 ases 3 0 maurLil 360 46.4 e.= 327 50.42 empu. Sp. h. 9.7 L,= 4. 2.82 unistee Ca ba nse g na pan 3Lt aCagTIguaC acawfla ta=>a 3039 4227.4 203.= 30109, 3318.49 Fan lLT Cf%ThuraGipat-Ce n twuPar.tb Co . seagatus Jte. 26.3 0.= 16 29.02 64410T t. t a l. t um l u n e, p.%t e#*hha n aPlue 15 CONo eaf els Sve. 83.S 6.= 129, 4S.00 FahlLT P ap at' a L4 4 0 es46 rawaCatas85 Cua55fp0%IDIS attu. 337.3 36.= 68%. 169.00 yamaCALa4u& PaWVuS SS. . 6.6 0= SS. 38.74 FarILT Pon tr e l.g us t Lapled.Ce.m a SCurT3 28, 3.4 c.= 27 9.55 FaW[LV f p. essa g o gg, Te.*nna teswn s wai a $$4 69.S 0.= ISI. 60.95 f%sure CICLurul fs a F a e l a.T n 8 f.e'e* S e'an sa t t ese.= a gs.y. BSeS. Sys.1 IJ.= 49%. 280.33 ,
own u w anw at t :(u t ria e#4tn. .sve. 735, 26.9 0.= lol. 39.48 L*l e".i p6:ss t lit a t eault.I i.o G. ... a .sP. .i.. i.i.. ai.= i9.. 14.3i D , D ,
~~@ q4 1 Fa 3Lt t a( es t ta g g en a s -~~
in
,a .t....,.,,, ,,4 m ml -) &,g 4 ........a .... ,,0., ... 9.. .
Su.eCI a%% Cf ew tre hl 4 uss a u. m a s.es. s t 438 894.6 0.= 219 94.94 ex t 9 (vrwss 98 4.6 4.= J4 9.0S s.a.rt.a u . a s.a rn3 : e, a t a
. . . . . % o. 4 . .s e. g .a . sr. 6%u. In.1 e,= .. 23.34 s, n* w s . s A P. .a *. e ..< e. a. e * ..e \ e a t e
~~I b e 8 e p . e e f 0~~
~~$M 9 E $ 5%~~
~~e> 9W Fbe he~~
~~>S S EW De W5 me es I f ; a > kJ ! ee Ok 6C em 0h S~~
~~4 4 6* 0E e% ., bW 3e Je se g af 3 kJ~~
~~ae 0>~~
~~> 0O a e>~~
e 9 4 Gm a s> n0 9 9 O e O 9 e 0 0 .d1 4 3 p e 0 0 $ e e e e 1 0 8A e e e e 6 9> fu ce E 9 9 e6 E GE
a. 9d 2 == W> * * *
~~fe 5 Je o a m n e g >~~
C
~~>J ee . E-eE a= O > re e se -uw as C# D=C E b> me t E of O g K 3 L* e 9 9 0 9 e.W Bua S~~
e 3 e e o 9 e e W es ap > a e&3e ed q e.-= se 82%= *8 ee &8 e S se 3 J e .1 sea se e a o se e m e J 2 3 ee es ao d & 9e e ao v g :a e a a . e
~~J* 8 d 'W e D~~
~~2 9 3 8 o e e e~~
~~> 0~~
~~e e 4 2 0 F se O e re~~
=
~~b P es L i t En h A e . a : [. e~~
~~~ ru - s o ? \,D ".~~
~~u .e 2 4 e D ,_~~
\D s v SE eD e 8. #. w 3b d3 bEC WI e W e e er s= 'J a > e - e' Ed g7 J e e= V eu OF .3
~~' 2 2 2 2 e 3 me O l 3 == 2==>=== m >~~
~~aa : W 3 em i~~
~~~ un sc: 4 2 .n u 3 em e ue J C g bew rs F M 8 24 E TF e%
~~y P == 4 ? = 2A te e2~~
~~== m a6 O J Je e e $ #4~~
~~W > >J J J 4 a e E =u u s.~~
~~b & # .= == A & I-B-122 e e~~
- . . _ _ _ _ _ . . . . . . .. __ __,.__..._...m__ , . . . . . . . _ . ___ .. . . . . . . . _ . . ~_____._.
i i Table B-4 (Cont.) i ma t t e. c.pa tweet. Cesent.LL e6;. CALF 4 6'n07 1919 hv a 18.ps. A e6PFJT FI'm FfMMITM 99a*Tip , , reuers,ams Tse, S Luelva Pow 6 m CrthPficatgetes pay , e Cesarlbel f t STsahClutt stupf AT ruf 5 Tab Fj f t.II P0mgp phan? ,
........hssetst as or I nes t y g tsesag q.......* * .......pr.m CeengC pLit.p...... ....et? DESCMT...= .....#T utIC#T.*.**
~~T a s tie~~
~~Ptaw e a uce. ATO DEU 10 Tab pransm3 Tufat stampe) i~~
,_..L ...... ,..... .W... ...... ....... ..... ..... ...... .....T ; !}}

ML19322E608

Contents

Text

SUMMARY

Background

:: - ',E

=s3Ad oee oee t-m

= 33e=

=

. se as CD b 3 3 t

=

a: =# r "ji.c" T 9

%

J =W A 3= T 39 . 3

. Ieo == 4 # = s

=

a 40e = 4 ** == p

amparsa sage.usmCa 25 357 S.s 18.3 0.

====muesta OF In01WIOUALS**=*

Navigation menu

ML19322E608

Text

SUMMARY

Background

:: - ',E

=s3Ad oee oee t-m

= 33e=

=

. se as CD b 3 3 t

=

a: =# r "ji.c" T 9

%

J =W A 3= T 39 . 3

. Ieo == 4 # = s

=

a 40e = 4 ** == p

amparsa sage.usmCa 25 357 S.s 18.3 0.

====muesta OF In01WIOUALS**=*

Navigation menu

Search