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Home My WebLink AboutNC0004987_Assessment of Balanced & Indigenous_20091102ASSESSMENT OF BALANCED AND INDIGENOUS POPULATIONS IN LAKE NORMAN NEAR MARSHALL STEAM STATION NPDES Permit No. NC0004987 Principal Investigators: Michael A. Abney William J. Foris James J. Hall RECEIVED NOV 2 2009 DUKE ENERGY DENR :, WATER QUALITY Corporate EHS Services POINT SOURCE BRANCH-. McGuire Environmental Center 13339 Hagers Ferry Road Huntersville, NC 28078 October 2009 ACKNOWLEDGMENTS The authors wish to express their gratitude to a number of individuals who made significant contributions to this report. First, we are much indebted to the EHS Scientific Services field staff in carrying out a complex, multiple -discipline sampling effort that provides the underpinning of this report. Kim Baker, Bob Doby, James Hall, Bryan Kalb, Glenn Long, and Todd Lynn were vital contributors in completing fisheries collections and sample processing. James Hall, Aileen Lockhart, Shannon McCorkle, and Jan Williams contributed in macroinvertebrate sampling, sorting and taxonomic processing. We would also like to thank multiple reviewers; including Penny Franklin, Duane Harrell, Ron Lewis, and John Velte. The insightful commentary and suggestions from these individuals, and also between co-authors, have benefited the report in myriad ways. ii TABLE OF CONTENTS EXECUTIVE SUMMARY.................................................................................................. iv LISTOF TABLES................................................................................................................ vi LISTOF FIGURES............................................................................................................. vii CHAPTER 1- INTRODUCTION........................................................................................1-1 CHAPTER 2- STATION OPERATION............................................................................ 2-1 BACKGROUND INFORMATION................................................................................ 2-1 THERMALDATA......................................................................................................... 2-2 CONCLUSIONS............................................................................................................. 2-3 CHAPTER 3- MACROINVERTEBRATES...................................................................... 3-1 MATERIALS AND METHODS.................................................................................... 3-1 RESULTS AND DISCUSSION..................................................................................... 3-2 Substrate....................................................................................................................... 3-2 WaterQuality............................................................................................................... 3-2 Density......................................................................................................................... 3-2 Taxa.............................................................................................................................. 3-3 CONCLUSIONS............................................................................................................. 3-4 CHAPTER4- FISH.............................................................................................................. 4-1 MATERIALS AND METHODS.................................................................................... 4-1 Summer Electrofishing Surveys.................................................................................. 4-1 Spring Electrofishing Surveys..................................................................................... 4-1 Fall Hydroacoustics and Purse Seine Surveys.............................................................4-2 Balanced and Indigenous Assessment......................................................................... 4-2 RESULTS AND DISCUSSION..................................................................................... 4-2 Summer Electrofishing Surveys.................................................................................. 4-2 Spring Electrofishing Surveys..................................................................................... 4-3 Fall Hydroacoustics and Purse Seine Surveys............................................................. 4-4 CONCLUSIONS............................................................................................................. 4-4 LITERATURECITED.......................................................................................................L-1 APPENDIXTABLES....................................................................................................... A-1 iii EXECUTIVE SUMMARY Annual monitoring of physicochemical characteristics and assessments of macroinvertebrate and fish populations at selected locations in Lake Norman continued through 2008, in accordance with an agreement with the North Carolina Department of Environment and Natural Resources (NCDENR). This report presents data collected from 2004 through 2008. Results of data analyses completed since submittal of the previous report in 2003 are reported and support renewal of the existing permitted thermal limits for Marshall Steam Station (MSS). MSS operated continuously from 2004 through 2008, and station operation during this period was similar to previous years. MSS operated at an average capacity of 77% over the five- year period. Monthly average discharge water temperatures at MSS were in compliance with NPDES permitted thermal limits of 93.9 °F (34.4 °C) July 1 through October 31 and 91.9 °F (33.3 °C) the rest of each year over this five-year period. Sampling of macroinvertebrate communities continued during 2004 — 2008. Beginning in 2005, water temperatures and dissolved oxygen levels were measured at each location in conjunction with macroinvertebrate sampling. The macroinvertebrate data exhibit substantial variability, however, the variability is consistent with that observed for historical data. The data for the current study exhibit the same general density and taxa diversity trends noted during the previous study period, except in 2006, when macroinvertebrate densities at the MSS discharge canal increased dramatically to 13,520/mz and were dominated by 14 taxa of Oligochaeta. Water temperatures were slightly higher in the MSS discharge canal, but overall, similar to other macroinvertebrate sampling locations. DO levels were much lower at the MSS discharge canal than other macroinvertebrate sampling locations. Current study results indicate that, overall, the macroinvertebrate densities and taxa diversity observed during 2004 — 2008 at locations uplake, downlake, and in the vicinity of MSS are indicative of balanced and indigenous macroinvertebrate communities in these locations. Monitoring and assessment of the fish communities near MSS also continued during 2004 — 2008 and indicated that a diverse fish community was present in the littoral portions of Lake Norman around MSS. Trophic groups present include planktivores, insectivores, omnivores, and piscivores. The MSS discharge canal yielded the highest total number of fish among IV locations, while also exhibiting the lowest DO (< 2.0 mg/L) among locations each summer. Spring fish collections were more variable among years. Current study results were consistent with previous years and similar to other Catawba River reservoirs. Lake Norman forage fish populations remained fairly stable during 2004 — 2008. Threadfin shad Dorosoma petenense remain the dominant species, and Alewife Alosa pseudoharengus numbers have been relatively low since 2004. Forage fish densities in Lake Norman are similar to those noted in other Catawba River reservoirs of similar trophic status. Based on the diversity and biomass of the Lake Norman littoral fish community, the abundance of fish in the MSS discharge canal, and the abundance of forage fish available to limnetic predators, it is concluded that the thermal regimes resulting from the operation of MSS have supported the protection and propagation of a balanced and indigenous fish community in Lake Norman. Comparison of MSS operation and environmental monitoring data indicate that balanced and indigenous populations of macroinvertebrates and fish continue to exist in Lake Norman in the vicinity of MSS. This supports a conclusion that the present thermal limits should be maintained when the Station NPDES permit is renewed. VA LIST OF TABLES Table Title 1-1 Description of Lake Norman sampling locations in the vicinity of MSS, CatawbaCounty, NC................................................................................ 2-1 Marshall Steam Station CCW flow rate for each unit for 1, 2, and 3 -pump Page ...........1-2 operation...................................................................................................................... 2-4 3-1 General descriptions of the substrate found at Locations A, B, F, and E in the vicinity of MSS during July of 2004 through 2008 .................................................... 3-5 3-2 Water quality parameters measured at the time of macroinvertebrate collections from Locations A, B, F, and E from 2004 — 2008 ...................................................... 3-5 3-3 Densities (no./m2) of macroinvertebrates collected annually from Location A (uplake of MSS) from 2000 — 2008............................................................................ 3-6 3-4 Densities (no./m) of macroinvertebrates collected annually from Location B (near MSS discharge) from 2000 — 2008.................................................................... 3-9 3-5 Densities (no./m2) of macroinvertebrates collected annually from Location F (mid -lake near MSS) from 2000 — 2008................................................................... 3-11 3-6 Densities (no./m2) of macroinvertebrates collected annually from Location E downlake of MSS from 2000 2008. 3-14 4-1 Number of individuals, percent composition, and number of species in summer electrofishing surveys from five locations (A — E) in Lake Norman, 1991— 1993, 1994 —1999, 2000 — 2003, and 2004 — 2008.............................................................. 4-6 4-2 Number of individuals, percent composition, and number of species in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 — 1997 and 1999, 2000 — 2003, and 2004 — 2008.......................................................... 4-7 4-3 Forage fish species composition and modal threadfin shad total length (TL) class in purse seine surveys in Lake Norman, 1993 — 2008 ................................................ 4-8 vi Figure Title, Page 1-1 Sampling locations on Lake Norman . ......................................................................... 1-3 2-1 The daily and monthly average water temperature (°F) of the condenser cooling 4-2 CPUE and number of fish species in summer electrofishing surveys from water discharged from MSS and percent capacity from January 1, 2004 through Location A in Lake Norman, 1994 — 2008............................................................... December31, 2008..................................................................................................... 2-5 3-1 Density (no./m2) of macroinvertebrates collected annually from Lake Norman Location B in Lake Norman, 1994 — 2008................................................................ near MSS from 2000 — 2008..................................................................................... 3-17 3-2 Total number of taxa collected annually from Lake Norman near MSS from 2000 Location C in Lake Norman, 1994. — 2008................................................................ —2008 ........................................................................................................................ 3-17 3-3 Density (no./m2) of Oligochaeta, Diptera, and Corbicula collected annually from Location D in Lake Norman, 1994 — 2008............................................................... Location A (uplake of MSS) from 2000 — 2008 ....................................................... 3-18 3-4 Density (no./m) of Oligochaeta, Diptera, and Corbicula collected annually from Location E in Lake Norman, 1994 — 2008................................................................ Location B (near MSS discharge) from 2000 — 2008 ............................................... 3-18 3-5 Density (no./m2) of Oligochaeta, Diptera, and Corbicula collected annually from and REF) in Lake Norman, 1993 — 1997, 1999 — 2008 ............................................ Location F (mid -lake near MSS) from 2000 — 2008 ................................................. 3-19 3-6 Density (no./m2) of Oligochaeta, Diptera, and Corbicula collected annually from and REF) in Lake Norman, 1993 — 1997, 1999 — 2008 ............................................ Location E (downlake of MSS) from 2000 — 2008 ................................................... 3-19 4-1 Sampling locations and zones associated with fishery assessments in Lake vii Norman........................................................................................................................ 4-9 4-2 CPUE and number of fish species in summer electrofishing surveys from Location A in Lake Norman, 1994 — 2008............................................................... 4-10 4-3 CPUE and number of fish species in summer electrofishing surveys from Location B in Lake Norman, 1994 — 2008................................................................ 4-10 4-4 CPUE and number of fish species in summer electrofishing surveys from Location C in Lake Norman, 1994. — 2008................................................................ 4-11 4-5 CPUE and number of fish species in summer electrofishing surveys from Location D in Lake Norman, 1994 — 2008............................................................... 4-11 4-6 CPUE and number of fish species in summer electrofishing surveys from Location E in Lake Norman, 1994 — 2008................................................................ 4-12 4-7 Number of fish collected in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 — 1997, 1999 — 2008 ............................................ 4-12 4-8 Biomass of fish collected in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 — 1997, 1999 — 2008 ............................................ 4-13 4-9 Number of fish species collected in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 —1997, 1999 — 2008 .................................. 4-13 4-10 Zonal and lake -wide population estimates of pelagic forage fish in Lake Norman, 1997 —2008 ............................................................................................................... 4-14 vii CHAPTER 1 INTRODUCTION Annual monitoring of physicochemical characteristics and assessments of macroinvertebrate and fish populations at selected locations in Lake Norman continued through 2008 (Table 1- 1 and Figure 1-1), in accordance with an agreement with the North Carolina Department of Environment and Natural Resources (NCDENR). Physicochemical and biological data were collected at locations near Marshall Steam Station (MSS) and included a location upstream of the facility (Location A), two sites within the immediate projected impact of MSS's discharge (Locations B and C) and three downstream recovery sites (Locations D, E, and F), presumably outside the influence of the effluent plume (Figure 1-1). The objectives of this on-going monitoring program are to provide an assessment of the balanced and indigenous nature of the biological populations in Lake Norman with respect to the thermal discharge from MSS and evaluate renewal of thermal limits at the station. The thermal limit for MSS is a monthly average discharge (i.e., end -of -pipe) temperature limit of 93.9 °F (34.4 °C) during July 1 through October 31, and 91.9 °F (33.3 °C) the rest of each year. Regulatory review of past studies have determined, pursuant to Section 316(a) of the Clean Water Act that the thermal discharge of MSS ensures the protection and propagation of balanced, indigenous populations in Lake Norman. This report presents data collected since submittal of the previous summary reports (Duke Power Company 1994; Duke Power 1999, 2004a) and includes data collected from 2004 through 2008. These data were also compared with other past and present on-going environmental monitoring programs conducted in this watershed. 1-1 Table 1-1. Description of Lake Norman sampling locations in the vicinity of MSS, Catawba County, NC. N Approximate river Report miles upstream of Location Duke Power the Cowans Ford Designation Location # Location Description County Hydro Longitude Latitude A 15.5 The first cove on the left upstream from MSS intake cove. Catawba 1 16.9 -80.9461 35.6163 First cove along northern shoreline going into the MSS CCW B 14.7 discharge cove. Catawba 13.9 -80.9573 35.5942 C 14.5 Inside MSS discharge canal. Catawba 13.9 -80.9644 35.5951 Large cove halfway between channel markers 14 & 15 on the D 13.0 west side of the channel. Catawba 12.7 -80.9527 35.5753 Cove formerly proposed for power plant site intake or E 19.0 discharge. Iredell 9.0 -80.9301 35.5297 Left shoreline, approximately 100 meters uplake of Channel F 34.0 Marker 13. Catawba 11.5 -80.9569 35.5544 N Lookout Shoals Hydro Cowans Ford Hydro McGuire Nuclear Station Figure 1-1. Sampling locations on Lake Norman. Duke Energy historical sampling location numbers are listed in parentheses. 1-3 CHAPTER 2 STATION OPERATION BACKGROUND INFORMATION Marshall Steam Station (MSS) is located on the western shore of Lake Norman (Figure 1-1) just north of Charlotte, North Carolina, in Catawba County. Its four generating units have a combined operating capability of 2,090 MWE-net. Units 1 and 2 are each rated at 385 MWE-net and began commercial operation in 1965 and 1966, respectively. Units 3 and 4 are each rated at 660 MWE-net and began commercial operation in 1969 and 1970, respectively. MSS receives once -through condenser cooling water (CCW) from below a skimmer wall located at the mouth of a 1.3 -mi (2.1 -km) long cove. The surface area of the cove is about 200 ac (81 ha) and its volume is approximately 250 million ft3 (7 million m). The skimmer wall was designed to retain the upper 60 ft (18.3 m) of water on the lake side of the wall at full pond. The opening below the skimmer wall through which the station CCW is withdrawn is about 10 ft (3 m) high and 270 ft (82.3 m) wide. Units 1 and 2 each have two condenser cooling water pumps, and Units 3 and 4 each have three condenser cooling water pumps. Typically, only one pump per generating unit is used during the cool winter months or when the unit is operating at reduced load. During the warmer summer months when units are operating at full -load, either two or three pumps per unit are generally used, depending on which units are operating. Maximum rates of cooling water flow are 423 cfs (12.0 cros) each for Units 1 and 2, and 709 cfs (20.1 cros) each for Units 3 and 4. Thus, the maximum possible station CCW flow rate is 2,264 cfs (64.1 cros). Under one pump per unit operation, the maximum CCW flow rate for the entire station is 1,230 cfs (34.8 cros). Refer to Table 2-1 for a listing of CCW flow rates for each unit under one-, two-, and three -pump operation. The condenser cooling water from MSS is discharged into a 1 -mi long cove. The discharge cove varies from a width of 75 ft (22.9 m) and depth of 33 ft (10.1 m) at the discharge structure to a width of 850 ft (259.1 m) and a depth of 50 ft (15.2 m) at the mouth of the discharge cove. The total area of the discharge cove is about 75 ac (30.4 ha). 2-1 Lake Norman can be classified as oligotrophic, or nutrient poor, based on 2007 assessments performed by the state in association with the Lake Assessment Program, which is conducted on a 5 -yr cycle (NCDENR 2008). Nutrient and algal biomass data collected monthly from May through September 2007 were consistently low or less than the laboratory reporting limits for the specific analyte, whereas metal concentrations were within applicable water quality standards. Turbidity levels were also low, and Secchi depths ranged from 1.8 to 2.6 m, indicating very good water clarity (NCDENR 2008). Elevated surface dissolved oxygen concentrations and dissolved oxygen saturation values were observed in the upper, riverine section of the reservoir, which is similar to that reported for 2002 (NCDENR 2003). Overall, these results are similar to those previously reported by the state (NCDENR 2003) and to other studies (MCDEP 2003, 2007, Duke Power 2005, and Duke Energy 2006, 2007, 2008) on Lake Norman. THERMAL DATA MSS is operated by Duke Energy as a base -load generating facility, and station operation during the period January 2004 through December 2008 was similar to previous years. MSS operated continuously from 2004 through 2008, with peak pumping of condenser cooling water during the summer. Electric generation, expressed as monthly average percent capacity, ranged from a minimum of 46% in November 2006 to a maximum of 94% in February 2004. MSS operated at an average capacity of 77% over the 5 -yr period. The seasonal cycle of discharge water temperatures at MSS over the period January 2004 through December 2008 (Figure 2-1) was similar to that observed in previous years (Duke Power Company 1994; Duke Power 1999, 2004). Monthly average discharge water temperatures at MSS were in compliance with NPDES permitted thermal limits of 93.9 OF (34.4 °C) July 1 through October 31 and 91.9 OF (33.3 °C) the rest of each year, over this 5 - yr time period (Figure 2-1). Discharge water temperatures ranged from a minimum monthly average of 67.6 OF (19.8 °C) in December 2008 to a maximum monthly average of 93.7 OF (34.3°C) in September 2005 (Figure 2-1). Average daily discharge temperatures ranged from a minimum of 59.0 OF (15.0 °C) in December 2008 to a maximum of 100.2 OF (37.9 °C) in September 2007 (Figure 2-1). Discharge temperatures are linked to a combination of local meteorological conditions and electrical generation. 2-2 CONCLUSIONS MSS operated continuously from 2004 through 2008 and station operation during this period was similar to previous years. Electric generation, expressed as monthly average percent capacity, ranged from a minimum of 46% in November 2006 to a maximum of 94% measured in February 2004. MSS operated at an average capacity of 77% over the 5 -yr period. During this 5 -yr period, monthly average discharge water temperatures at MSS were in compliance with NPDES permitted thermal limits of 93.9 OF (34.4 °C) July 1 through October 31 and 91.9 OF (33.3 °C) the rest of each year. 2-3 Table 2-1. Marshall Steam Station CCW flow rate for each unit for 1, 2, and 3 -pump operation. Unit Number 1 -Pump cfs 2 -Pump cfs 3 -Pump cfs 1 281 423 N/A' 2 281 423 N/AI 3 334 564 709 4 334 564 709 Station Total 1,230 1,974 2,264 I Units 1 and 2 have only two CCW pumps available. 2-4 LL 120 100 80 I 40 20 100% 80% n 60% o 40% 0 n 20% p 0% Figure 2-1. The daily and monthly average water temperature (°F) of the condenser cooling water discharged from MSS and percent N capacity from January 1, 2004 through December 31, 2008. C- a C- o C- a` o a o a o a C- o 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 � 4N � � 0 0 C' cn 0 0 01 G1 -4 .i ~ v CO CO CO 00 100% 80% n 60% o 40% 0 n 20% p 0% Figure 2-1. The daily and monthly average water temperature (°F) of the condenser cooling water discharged from MSS and percent N capacity from January 1, 2004 through December 31, 2008. CHAPTER 3 MACROINVERTEBRATES MATERIALS AND METHODS Benthic macroinvertebrate sampling was conducted annually in late July of each year from 2004 — 2008 as part of the continuing monitoring program for Marshall Steam Station (MSS). As in previous years, samples were collected from four locations on Lake Norman; Location A (uplake of MSS), Location B (MSS discharge canal), Location F (just north of Channel Marker 13), and Location E (downlake) (Table 1-1 and Figure 1-1). In previous reports (Duke Power Company 1994, Duke Power 1999, and Duke Power 2004a), Location F was denoted as Location D only for benthic macroinvertebrate collections. Historically, Location F was denoted Location 34.0. A petite ponar dredge (15.3 x 15.3 cm) was used to collect five sample replicates at each location. Samples were collected at depths ranging from two to three m to bracket the depth of peak benthic abundance (Brinkhurst 1974). Samples were washed through a 500-µm mesh sieve and individually preserved with 70% ethanol containing rose bengal stain. The substrate at each location was identified and recorded based on a visual analysis of substrate types, during the sieving process. Organisms were sorted in the laboratory and identified to the lowest practicable taxon. Macroinvertebrate densities were calculated by extrapolating ponar densities to a standard one mZ bottom area. The assessment of the balanced and indigenous nature of the benthic community in the vicinity of MSS was determined by comparing macroinvertebrate densities and taxa abundance among the sample locations. Beginning in 2005 in conjunction with macroinvertebrate sampling, a pre -calibrated YSI Model 55 handheld dissolved oxygen (DO) meter was used to measure water temperature and DO just above the sediment at each location. Starting in 2008, water temperatures and DO values were measured in situ, using a pre -calibrated Hach®HQ40d water quality meter. 3-1 RESULTS AND DISCUSSION Substrate Typically, the substrate was similar at all locations, being composed primarily of silt, sand, and organic matter (om). Clay was observed in the substrate at Location E in 2005 and Location B in 2008 (Table 3-1). Water Ouality Water temperatures observed during sampling from 2005 — 2008 ranged from 27.1 — 33.9 °C (Table 3-2). The lowest temperature each year generally varied between locations and ranged from 27.1 to 29.2 °C, but Location B (MSS discharge location) had the highest temperature each year ranging from 29.5 to 33.9 °C. The lowest temperature for all locations occurred in 2007. The DO observed from 2005 — 2008 ranged from 1.3 to 8.8 mg/L (Table 3-2). The lowest DO each year occurred at Location B, ranging from 1.3 to 2.3 mg/L, and the highest DO varied each year among Locations A, E, and F, ranging from 6.5 to 8.8 mg/L. Both temperature and DO values were generally similar at Locations A, E, and F each year. Densily During 2004 — 2008, overall annual macroinvertebrate densities varied substantially among years and locations (Tables 3-3 through 3-6 and Figure 3-1). The highest annual density was reported at Location A in 2004 and 2008, Location F in 2005 and 2007, and Location B in 2006 (Figure 3-1). The annual densities in 2004 at Locations A and F were the highest densities reported for these locations during this reporting period (Tables 3-3 through 3-6 and Figure 3-1). Densities at Location A decreased from 2005 through 2007 but increased in 2008, when it was the highest reported density for the four locations that year. Densities at Location F decreased each year from 6,706/mz in 2004 to 3,256/m2 in 2008, but Location F still had the highest density of any location in 2005 and 2007 (Table 3-5 and Figure 3-1). Densities at Location B decreased from 2004 to 2005 but increased in 2006 to 13,520/m2, which was the highest reported density for all of the locations from 2004 — 2008 (Table 3-4 and Figure 3-1). Oligochaeta represented by 14 taxa made up 86.6% (11,692/mz) of the total density at Location B in 2006. The family Tubificidae, represented by five taxa, made up 3-2 76.5% (10,349/mz) of the total density at Location B in 2006 (Table 3-4). Milligan (1997) stated that Tubificids frequently form dense populations in organically enriched habitats with a silty or muddy substrate tending toward anoxic conditions. Densities at this location decreased sharply in 2007 to 2,110/mz and continued to decrease in 2008. Location E generally had the lowest density among all locations each year (Figure 3-1). Densities from 2004 — 2008 at each location, with the exception of Location B in 2006, were similar to those reported from 2000 — 2003 (Duke Power 2004a). Taxa The number of macroinvertebrate taxa collected at a location is typically a good indicator of the overall diversity and the presence of a balanced indigenous population. Taxa abundance from 2004 — 2008 varied temporally and spatially (Tables 3-3 through 3-6 and Figure 3-2). Generally, the taxa abundance decreased from 2004 to 2005 and then increased to the highest number of taxa in 2006. The highest number of taxa collected from Locations B and F occurred in 2006 and at Locations A and E in 2008 (Figure 3-2). Overall, the highest number of taxa was collected at Location F (43 taxa) in 2006 and the lowest from Locations t ' E and B (20 taxa), in 2005 and 2008, respectively. The fewest number of taxa collected each year from 2004 — 2008 occurred at Location B (MSS discharge canal) three out of the five years. Overall, the number of taxa collected from 2004 — 2008 was generally similar to those reported from 2000 — 2003 (Duke Power 2004a). Macroinvertebrate populations at each location from 2004 — 2008 were comprised primarily of Oligochaeta, Diptera, and Corbicula taxa (Figures 3-3 through 3-6). As observed with overall densities (Figure 3-1), Oligochaeta, Diptera, and Corbicula densities varied by location and year (Figures 3-3 through 3-6). Generally, either Oligochaeta or Diptera taxa dominated samples at each location from 2004 — 2008, but Corbicula were most abundant at Locations A and F in 2004 and Locations F and E in 2005. Diptera had the highest abundance at Location A in 2005 but was replaced by Oligochaeta from 2006 — 2008 (Figure 3-3). Location B in 2006 had the highest macroinvertebrate density for this reporting period (13,520/mz), with Oligochaeta representing 87% of the total density (Figure 3-4). Corbicula densities at Location B from 2004 — 2008 were extremely low, ranging from 0/m2 (2005 and 2006) to 17/m2 (2007). Similar numbers were reported for Corbicula at this location from 2000 — 2003 (Figure 3-4). Corbicula densities at Location F decreased dramatically between 2005 and 2006, and from 2006 — 2008, the highest densities alternated between Diptera and Oligochaeta (Figure 3-5). Location E samples from 2004 — 2008 were generally dominated 3-3 by either Oligochaeta or Diptera, except in 2005 when Corbicula were most abundant (Figure 3-6). CONCLUSIONS The water quality parameters (temperature and DO) taken at the time of macroinvertebrate collections did not suggest any negative impact to the benthic communities. The only water quality issue may be related to the low DO value each year at Location B, which could be expected since MSS pulls its CCW from the bottom of Lake Norman (See Chapter 2 of this report). Overall, macroinvertebrate densities and numbers of taxa were generally slightly lower at Location B (MSS discharge canal), except in 2006, when the density at this location was the highest recorded for 2000 — 2008 and was comprised mainly of Oligochaeta (87% representing 14 of the 37 taxa). Slightly lower densities and numbers of taxa at this location would be expected, due to the warmer water discharged from MSS. Higher densities and taxa numbers collected at Location A (uplake of MSS), Location F (midlake near Channel Marker 13), and Location E (downlake) indicate that there are no apparent thermal effects L from the MSS heated discharge on the macroinvertebrate communities at these locations. Based on macroinvertebrate densities and taxa diversity observed during 2004 — 2008, the macroinvertebrate communities at these locations in the vicinity of MSS represent balanced and indigenous populations. 3-4 Table 3-1. General descriptions of the substrate found at Locations A, B, F, and E in the vicinity of MSS during July of 2004 through 2008. Substrates are listed in order of the most prevalent type first. Organic matter (om) is typically composed of small sticks, leaf and/or grass fragments, etc. Year A B F E 2004 silt silt silt sand DO (mg/L) om om om om Tem °C sand sand sand silt 2005 sand sand silt clay DO (mg/L) om om om om Tem °C 28.6 32.4 sand sand 2006 silt silt silt silt DO (mg/L) sand om om om Tem °C om sand sand sand 2007 silt silt silt silt DO (mg/L) sand sand om sand Tem °C om om sand om 2008 silt silt silt clay DO (mg/L) om clay sand silt Tem °C 30.5 om om om Table 3-2. Water quality parameters measured at the time of macroinvertebrate collections from Locations A, B, F, and E from 2004 - 2008. Year A B F E 2004 DO (mg/L) N/A N/A N/A N/A Tem °C N/A N/A N/A N/A 2005 DO (mg/L) 6.9 2.3 7.3 7.3 Tem °C 28.6 32.4 29.2 28.9 2006 DO (mg/L) 6.8 1.6 5.7 7.0 Tem °C 29.5 33.9 30.0 28.8 2007 DO (mg/L) 6.5 1.3 5.5 6.5 Tem °C 27.6 29.5 27.4 27.1 2008 DO (mg/L) 7.8 1.5 8.8 7.8 Tem °C 30.5 33.1 29.2 30.1 3-5 Table 3-3. Densities (no./m2) of macroinvertebrates collected annually from Location A (uplake of MSS) from 2000 — 2008. Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Annelida Hirudinea Rh nchobdellida Glossiphoniidae Helobdella spp. 77 9 Oli ochaeta Tubificida Naididae 17 9 69 Arcteonais lomondi 9 Dero flabelliger 26 9 9 Nais behningi 9 Naffs communis 17 52 34 86 86 Nais simplex 9 Nais variabilis 43 9 9 43 77 26 Pristina aequiseta 9 Pristina breviseta 9 Pristina sima 52 1 9 9 43 Pristinella osborni 9 9 34 17 Ripistes parasita 95 17 St laria lacustris 34 26 Uncinais uncinata 52 9 456 Tubificidae 697 2,196 1,059 491 654 138 706 775 491 Aulodrilus Amnobius 1 1 103 77 26 276 181 146 Aulodrilus i ueti 26 17 9 Branchirua sowerbyi 43 172 499 112 121 52 129 Umnodrilus hoffineisterei 17 9 Potamothrix vejdovsk i 43 Tubifex harmani 60 Tubifex tubifex 26 95 258 913 Pol chaeta Sabellida Sabellidae Manayunkia speciosa 534 629 2,781 34 784 112 34 9 Arthropoda Acari 17 Coleoptera Elmidae Macron chus glabratus 9 Insecta Diptera Ceratopo onidae Pal om ia-Bezzia complex 17 9 34 52 34 17 34 17 Chaoboridae Chaoborus spp. 17 C hi ronom idae-Chironom inae Axarus spp. 9 Chironomus spp. 17 3-6 Table 3-3. (Continued). Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Cladopelma spp. 34 Cladotan tarsus spp. 164 155 405 1,025 887 474 77 95 189 C tochironomus spp. 86 34 60 60 95 34 69 224 103 Cryptotendipes spp. 17 52 43 17 129 17 26 155 Demicryptochironomus spp. 1 9 Dicrotendipes modestus 9 Dicrotendipes neomodestus 9 34 26 .60 9 34 Glyptotendipes spp. 9 Microchironomus spp. 77 Pagastiella spp. 17 26 17 26 Parachironomus spp. 9 Paralauterborniella spp. 9 43 9 Paralauterborniella ni rohalteralis 17 Polypedilum spp. 34 Polypedilum flavum 9 Pol pedilum halterale 69 17 284 69 52 17 17 34 Pol pedilum scalaenum 17 1 9 52 43 Pseudochironomus spp. 103 9 34 Stempellina spp. 60 69 60 9 Stictochironomus spp. 52 706 9 370 146 224 672 189 878 Tanytarsus spp. 9 241 121 103 86 353 26 17 43 Chironomidae-Orthocladiinae Nanocladius spp. 9 Ablabesm is spp. 17 9 17 Ablabesm is annulata 34 26 9 9 Ablabesmyia Lanta 9 17 Ablabesm is mallochi 34 34 9 Coelotan pus spp. 52 138 52 26 43 95 D'almabatista pulchra 1 9 1 1 86 1 34 Procladius spp. 215 181 86 258 86 77 Procladius (Holotan pus) sp. 17 34 Procladius bellus 155 Ephemeroptera Caenidae Cams spp. 17 34 9 138 336 77 60 155 103 Ephemeridae Hexagenia spp. 9 34 17 69 77 26 9 9 Megaloptera Sialidae Sialis spp. 1 17 17 17 Odonata-Zygoptera Coenagrionidae Argia spp. 9 Trichoptera Hydropsychidae Cheumatops the spp. 86 H droptilidae H droptila spp. 17 9 17 Orthotrichia spp. 52 17 Leptoceridae 3-7 Table 3-3. (Continued). Taxa 2000 2001 2002 2003 20041 2005 2006 2007 2008 Oecetis spp. 43 34 17 17 52 Pol centro odidae Pol centro us spp. 9 9 Mollusca Pelecypoda Heterodonta Corbiculidae Corbicula fluminea 258 138 1,214 611 2,437 904 34 181 293 Veneroida Sphaeriidae 181 Sphaerium spp- 9 413 413 43 267 Nematoda 17 1 9 17 9 95 43 172 Nemertea Eno la Hoplonemertea Tetrastemmatidae Prostoma graecens 26 Platyhelminthes Turbellada Tdcladida Planariidae Du esia spp. 9 Total Density for Year 2,102 4,888 6,157 4,719 6,793 3,557 3,265 2,620 5,114 Total Taxa for Year 21 31 21 36 31 27 34 29 37 3-8 Table 3-4. Densities (no./m) of macroinvertebrates collected annually from Location B (near MSS discharge) from 2000 — 2008. Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Annelida Hirudinea Rh nchobdellida Glossiphoniidae Helobdella spp. 26 Oligochaeta Tubificida Naididae 26 Naffs communis 155 9 9 Nais variabilis 276 43 Bratislavia unidentata 69 Dero trifida 9 Dero vaga 344 Haemonalis waldvojeli 26 Pristina breviseta 69 Pristina sima 69 Pristinella osborni 232 Uncinais uncinata 103 Tubificidae 560 3,134 474 86 60 17 2,170 17 34 Aulodrilus limnobius 34 9 43 5,200 207 9 Aulodrilus pigueti 1 852 1,6451 207 1,739 499 43 Aulodrilus pludseta 34 Branchirua sowerb i 69 26 52 1,033 112 146 Limnoddlus hofteisterei 9 9 207 Potamothrix ve'dovsk i 17 Polychaeta Sabellida Sabellidae Mana unkia speciosa 34 60 17 17 17 17 Arthropoda Acari 9 Insecta Diptera Ceratopo onidae Pal om ia-Bezzia complex 17 95 9 52 43 9 129 26 26 Chaoboridae Chaoborus spp. 232 121 9 129 34 86 Chironomidae-Chironominae Chironomus spp. 26 9 9 9 9 Cladopelma spp. 60 138 17 26 52 Cladotanytarsus spp. 9 9 17 Cryptochironomus spp. 17 43 26 129 103 9 17 9 Cryptotendipes spp. 353 405 181 77 336 95 327 207 26 Dicrotendi es neomodestus I 1 1 17 1 9 9 Harnischia spp. 34 9 9 1 52 Microchironomus spp. 17 Nilothauma spp. 9 17 3-9 Table 3-4. (Continued). Taxa 2000 2001 2002 2003 20041 2005 2006 2007 2008 Pagastiella spp. 17 43 34 60 34 112 9 Paralauterbormella spp. 17 Phaenopsectra spp. 9 Pol pedilum halterale 77 69 52 1,093 52 26 310 26 26 Pseudochironomus spp. 9 9 69 26 34 Stictochironomus spp. 17 9 9 Tanytarsus spp. 34 69 26 232 26 69 69 Chironom idae-Orthoclad i i nae Parakiefferiella spp. 26 Chi ronom idae-Tanypod inae Ablabesmyia spp. 17 34 Ablabesmyia annulata 34 9 189 103 77 112 52 189 189 Ablabesmyia mallochi 34 9 Ablabesmyia janta 9 Clinotanypus spp. 17 9 17 Clinotanypus pinguis 9 Coelotanypus spp. 138 1 121 60 1 129 43 77 69 301 258 Djalmabatista pulchra 9 Procladius spp. 17 9 224 336 207 189 362 129 43 Procladius Holotan us sp. 9 155 Procladius bellus 9 52 Ephemero tera Caenidae Caenis spp. 9 9 9 Ephemeridae Hexagema spp. 26 26 138 52 103 155 34 121 224 M alo tera Sialidae Sialis spp. 9 1 9 17 Odonata-Aniso tera Corduliidae 9 Neurocordulia spp. 34 Trichoptera H dro s chidae Cheumatops the spp. 9 Leptoceridae Oecetis spp. 9 17 9 189 34 9 9 9 Mollusca Pelec poda Heterodonta Corbiculidae Corbicula fluminea 9 26 17 9 17 9 Nematoda 43 34 34 9 69 103 Nemertea Enopla Ho lonemertea Tetrastemmatidae Prostoma graecens 9 Total Density for Year 1,7391 4,677 1,534 3,668 1 3,0571 1,200 13,520 2,110 1,353 Total Taxa for Year 22 1 23 17 30 1 26 1 25 37 23 20 3-10 Table 3-5. Densities (no./m2) of macroinvertebrates collected annually from Location F (mid -lake near MSS) from 2000 — 2008. Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Annelida Hirudinea 17 Rhynchobdellida Glossiphoniidae Helobdella spp. 17 69 189 43 60 Oligochaeta Tubificida Naididae 26 17 Allonais pectinata 17 17 17 26 Bratislavia unidentata 9 Dero vaga 52 Nais communis 9 77 52 52 Nais variabil' 103 43 17 Ophidonais serpentia 26 Pristina acuminata 26 Pristina sima 26 69 17 26 Pristinella spp. 43 Pristinella osborni 43 9 95 60 9 Stephensoniana tandyi 9 Stylaria lacustris 9 26 Uncinais uncinata 34 9 146 Tubificidae 758 689 723 706 551 680 1,429 1,240 629 Aulodrilus limnobius 17 482 138 86 112 77 Aulodrilus pigueti 9 Bothrioneurum vejdovskyanum 9 9 9 Branchirua sowerbyi 60 69 77 103 60 34 Limnodrilus hoffineisterei 9 Potamothrix vejdovski 9 17 Spirosperma nikolskyi 9 Stephensoniana tandyi 9 Tubifex harmani 52 Tubifex tubifex 26 34 17 189 112 Lumbriculida Lumbriculidae 9 Lumbriculus spp. 26 Polychaeta Sabellida Sabellidae Manayunkia speciosa 1,205 3,633 146 818 17 1,558 775 1,498 189 Crustacea Amphipoda Talitridae 3-11 Table 3-5. (Continued). Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Hyalella azteca 9 Insecta Diptera Ceratopogonidae 1 1 52 Palpomyia-Bezzia complex 17 34 43 95 17 9 95 17 9 Chaoboridae Chaoborus spp. 17 9 Chironomidae-Chironominae 9 Chironomus spp. 9 Cladopelma spp. 9 Cladotanytarsus spp. 26 370 112 585 353 379 456 474 146 Cryptochironomus spp. 34 138 17 77 138 77 241 310 155 Cryptotendipes spp. 77 129 146 387 310 60 276 77 224 Demicryptochironomus spp. 1 34 9 Dicrotendipes neomodestus 9 Harnischia spp. 17 9 Nilothauma spp. 9 9 Pagastiella spp. 9 9 9 9 9 Paralauterborniella spp. 1 34 1 26 34 9 95 Paralauterbomiella nigrohalteralis 9 34 121 26 Polypedilum halterale 26 17 60 198 155 207 9 Polypedilum scalaenum 181 Pseudochironomus spp. 9 9 60 9 9 69 34 9 Stempellina spp. 17 52 34 198 60 60 9 Stenochironomus spp. 9 Stictochironomus spp. 26 284 69 77 103 26 258 189 Stictochironomus caffranius 69 Tanytarsus spp. 43 181 250 112 258 465 77 224 Chironom idae-Orthocladiinae Parakiefferiella spp. 9 9 43 9 Chironom idae-Tanypodinae Ablabesmyia annulata 9 9 Ablabesmyia janta 9 9 9 Ablabesmyia mallochi 34 9 77 9 17 Clinotanypus spp. 9 Coelotanypus spp. 34 9 43 9 34 60 Djalmabatista pulchra 17 77 17 Procladius spp. 9 34 138 34 198 34 60 224 Procladius bellus 17 Ephemeroptera Ephemeridae Hexagenia spp. 9 9 3-12 Table 3-5. (Continued). Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Plecoptera Perlidae Neoperla spp. 9 Odonata-Anisoptera Gomphidae Dromogomphus spp. 9 Trichoptera Leptoceridae Nectopsyche exquisita 17 9 26 Oecetis spp. 17 9 34 Polycentropodidae Polycentropus spp. 17 17 Cyrnellus fraternus 9 Mollusca Pelecypoda Heterodonta Corbiculidae Corbicula flumina 2,824 801 1,231 1,946 3,022 2,049 198 715 146 Veneroida Sphaeriidae Pisidium spp. 947 Sphaerium spp. 69 112 34 1,093 422 129 60 17 Nematoda 77 138 17 250 Nemertea Enopla Hoplonemertea Tetrastemmatidae Prostoma graecens 77 26 60 77 172 Platyhelminthes Turbellaria Tricladida Planadidae Du esia spp. 26 9 17 Total Density for Year 5,347 7,483 2,797 5,880 6,706 6,408 6,319 5,762 3,256 Total Taxa for Year 24 19 22 30 28 29 43 34 38 3-13 Table 3-6. Densities (no./m2) of macroinvertebrates collected annually from Location E (downlake of MSS) from 2000 — 2008. Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Annelida Hirudinea Rhynchobdellida Glossiphoniidae Helobdella spp. 34 Oligochaeta Naididae 172 9 17 Allonais pectinata 9 Nais communis 17 26 Nais variabilis 9 26 17 Pristina longisoma 9 Pristinella spp. 17 Ripistes parasita 9 Stylaria lacustris 9 9 Tubificida Tubificidae 766 1,180 43 379 327 267 155 112 103 Aulodrilus limnobius 456 310 129 26 121 Aulodrilus pigued 52 17 17 Bothrioneurum vejdovskyanum 9 Branchirua sowerbyi 26 138 9 69 9 Umnodrilus hoffineisterei 9 Tubifex tubifex 60 86 129 Polychaeta Sabellida Sabellidae Manayunkia speciosa 344 2,144 86 43 181 9 Arthropoda Acari 17 Insecta Diptera Ceratopogonidae Palpomyia-Bezzia complex 138 52 43 60 17 26 9 34 Chaoboridae Chaoborus spp. 26 9 Chironomidae-Chironom inae Chironomus spp. 17 9 60 9 26 Cladopelma spp. 9 9 Cladotanytarsus spp. 250 86 17 1 155 103 1 129 9 26 Cryptochironomus spp. 112 138 17 1 9 60 1 26 9 26 17 Cryptotendipes spp. 69 103 207 26 155 17 34 10334 Dicrotendipes neomodestus 17 9 52 17 Glyptotendipes spp. 9 3-14 Table 3-6. (Continued). Taxa 2000 2001 20021 2003 2004 2005 2006 2007 2008 Harnischia spp. 60 Pagastiella spp. 103 9 34 Pagastiella ostansa 43 Paralauterbomiella spp. 34 9 9 Paralauterborniella nigrohalteralis 26 34 Polypedilum halterale 60 241 17 69 26 34 Pseudochironomus spp. 34 69 34 103 9 Stempellina spp. 129 34 52 17 9 26 9 Stictochironomus spp. 138 9 26 43 26 Stictochironomus caffranius 26 Tanytarsus spp. 138 585 52 181 327 146 34 164 17 Tribelos spp. 17 Chironom idae-Orthocladiinae Chaetocladius spp. 9 Cricotopus spp. 9 Parakiefferiella spp. 34 Thienemanniella spp. 17 Chi ronom idae-Tanypodi n ae Ablabesmyia spp. 69 129 9 Ablabesmyia annulata 9 52 17 17 9 Ablabesmyia janta 26 121 77 26 Ablabesmyia mallochi 9 121 52 34 9 43 52 86 26 Coelotanypus spp. 138 17 9 34 86 189 Djalmabatista pulchra 34 121 17 9 Procladius spp. 9 86 146 95 164 86 86 Procladius (Holotanypus) sp. 17 103 Procladius bellus 86 17 Ephemeroptera Baetidae Acentrella spp. 9 Caenidae Caenis spp. 26 Ephemeridae Hexagenia spp. 112 9 9 69 17 9 Megaloptera Sialidae Sialis spp. 26 26 17 43 9 9 17 Odonata-Zygoptera Coenagrionidae Argia spp. 9 9 17 Trichoptera Hydroptilidae 3-15 Table 3-6. (Continued). Taxa 2000 2001 2002 2003 2004 2005 2006 2007 2008 Orthotrichia spp. 17 9 Leptoceridae Oecetis spp. 34 9 60 26 Polycentropodidae Cyrnellus fraternus 9 Polycentropus spp. 34 121 9 86 9 26 9 Mollusca Pelecypoda Heterodonta Corbiculidae Corbicula fluminea 629 672 224 43 611 2,006 69 95 439 Veneroida Sphaeriidae 17 Sphaerium spp. 103 77 60 77 17 Nematoda 69 9 9 Nemertea Enopla Hoplonemertea Tetrastemmatidae Prostoma graecens 34 9 9 Tiatyhelminthes Turbellaria Tricladida Planariidae Dugesia spp. 17 Total Density for Year 3,237 6,199 1,294 1,587 2,885 3,574 1,268 1,345 1,490 Total Taxa for Year 24 25 28 31 28 20 28 27 30 3-16 oo *e 4n oa no-- L) oe � � uo � r 15 10 o E I , 1A: . o u000 2001 000u u000 2004 oonm u000 000r 000u oAoB F E Figure 3'1. Density (no./2 ofmauroinvertebrateo collected annually from Lake Norman near MSS from 200O-2008. 10,000 o,0uu � s.mm o.onu � 4.mm 12 a.000 u.ono 1,000 E 'Ell E 'a E E 0 !� . _ . E [A , , , t I- _ I " i u000 2001 000u onuo uoo+ unoe 000e uonr uooa o/4 mB ''F E Figure 3-2. Total number of taxa collected annually from Lake Norman near M88 from 2000-2000. 3-l7 2,500 2,000 Location A c 1,000 500 0 2000 2001 2002 2003 2004 2005 2006 2007 2008 m Oligochaeta o Diptera Corbicula Figure 3-3. Density (no./m2) of Oligochaeta, Diptera, and Corbicula collected annually from Location A (uplake of MSS) from 2000 — 2008. Location B 3,500 3,000 2,500 N 1= 0 2,000 C T c 1,500 CD O 1,000 500 0 2000 2001 2002 2003 2004 2005 2006 2007 2008 m Oligochaeta 0 Diptera , Corbicula Figure 3-4. Density (no./m2) of Oligochaeta, Diptera, and Corbicula collected annually from Location B (near MSS discharge) from 2000 — 2008. 3-18 Location 3,500 ---'–'--'-'--'—'--'---'--------------------- 3,0o o,0oo � � 1.mm 17 1,000 sno o unno 2001 unoo uuno 2004 uuue uoom uour 0000 oO|igoohoega oDiptams ``Conbicula c Figure 3-5. of�li�o��,�� a�Co��u�uoll��d��bmm Density ' ' ' ) Location F(oid-lxkenear MSS) from 2O00 -20O8. Location 2,500 -------------------------------------------------- o,0oo 1,500 w 1.00n o 500 o u000 2001 uouo uuoo 2004 uoos uooe 2007 unna nO|igochoata oDiptero ^' Cmrb/cule z Figure 3-6. Density (nm./n�) of Oligoubootu, Diptera, and Cwn)icu/u collected annually from Location B(dnvvolukuofMSS) from 2000-2000. S -l9 CHAPTER 4 FISH MATERIALS AND METHODS Summer Electrofishing Surveys Electrofishing surveys were conducted in Lake Norman near Marshall Steam Station (MSS) in July (2004 — 2008) at five locations: one uplake from the MSS intake (Location A), two in the MSS discharge canal (Locations B and C), and two downlake from the MSS discharge (Locations D and E; Table 1-1 and Figure 1-1). The locations surveyed consisted of 100-m transects on both the left and right shorelines. Surface water temperature (°C) and dissolved oxygen (DO, mg/L) were measured with a calibrated thermistor and DO probe, respectively, at each location. Stunned fish were collected by two netters, identified to species, and measured for total length (TL, mm). Catch per unit effort (CPUE, number of individuals/200 i m) and the number of species were calculated for each sampling location. Spring Electrofishing Surveys Electrofishing surveys were conducted in Lake Norman in March or April (2004 — 2008) at two areas (Figure 4-1): near MSS (Zone 4) and at a reference (REF, Zone 3) area located between McGuire Nuclear Station and MSS. Ten 300-m shoreline transects were surveyed in each area and were identical to historical locations surveyed since 1993. Transects included habitats representative of those found in Lake Norman. Shallow flats where the boat could not access within 3-4 m of the shoreline were excluded. All sampling was conducted during daylight, when water temperatures were expected to be between 15 and 20 °C. Stunned fish were collected by two netters and identified to species. Fish were enumerated and weighed in aggregate by taxon, except for largemouth bass Micropterus salmoides and spotted bass M. punctulatus, where TL and weight (g) were obtained for each individual collected. Surface water temperature (°C) was measured with a calibrated thermistor at each location. Catch per unit effort (number of individuals/3,000 m) and the number of species were calculated for each sampling area. 4-1 Fall Hydroacoustics and Purse Seine Surveys Abundance and distribution of pelagic forage fish in Lake Norman were determined using mobile hydroacoustic (Brandt 1996) and purse seine (Hayes et al. 1996) techniques. The lake was divided into six zones (Figure 4-1) due to its large size and habitat spatial heterogeneity. An annual mobile hydroacoustic survey of the entire lake was conducted in mid-September with multiplexing, side- and down -looking transducers to detect surface - oriented fish and deeper fish (from 2.0-m depth to the bottom), respectively. Annual purse seine samples were also collected in mid-September from the downlake (Zone 1), midlake (Zone 2), and uplake (Zone 5) areas of Lake Norman. The purse seine measured 122.0 x 9.1 m, with a mesh size of 4.8 mm. A subsample of forage fish collected from each area was used to estimate taxa composition and TL size distribution. Balanced and Indigenous Assessment Annual summer electrofishing surveys are used to assess the balanced and indigenous nature of the Lake Norman fish community and provide information relative to potential MSS impacts. The assessment includes a comparison of CPUE and number of species data from locations uplake of, downlake of, and in the discharge canal of MSS during summer electrofishing. Spring electrofishing and hydroacoustic surveys near MSS began as part of the Catawba-Wateree hydroelectric relicensing activities and continue as a means to monitor the Lake Norman fishery. RESULTS AND DISCUSSION Summer Electrofishing Surveys Summer electrofishing surveys from 2004 — 2008 produced 3,187 individuals comprising seven families, 20 species, and two hybrid centrarchid combinations (Table 4-1, Appendix Tables A-1 to A-5). The species composition for the combined summer electrofishing surveys was dominated by centrarchids (90.4%), with cyprinids (6.7%) and clupeids (2.2%) greater than 1.0% each, and the remaining families representing less than 1.0% of individuals combined. Previously reported data from summer 2000 — 2003 also documented dominance by centrarchids (77.0%) with more cyprinids (21.3%). Spotted bass have steadily increased 4-2 in percent composition from being absent prior to 2005 to approximately 8.0% of individuals collected in 2008. Pollution tolerant species (i.e., longnose gar Lepisosteus osseus, goldfish Carassius auratus, common carp Cyprinus carpio, golden shiner Notemigonus crysoleucas, white catfish Ameiurus catus, redbreast sunfish Lepomis auritus, green sunfish L. cyanellus, and hybrid sunfish; NCDENR 2008) represented 12.2% of the collected fish during summer 2004 — 2008. This percentage of pollution tolerant individuals has decreased from 18.2% of the collected fish reported from summer 2000 — 2003. From 2004 — 2008, location CPUE ranged from 10.0 (Location D in 2007) to 264.0 fish/200 in (Location E in 2008; Figures 4-2 to 4-6), and the number of species ranged from two (Location D in 2007) to 11 species (Location E in 2008). Although Location C (MSS discharge canal) had the lowest DO (< 2.0 mg/L) in all years, it typically had the highest total number of individuals and resulting CPUE, likely due to deep riprap habitat and large bluegill populations. Summer electrofishing data are consistent with previously reported data (Duke Power Company 1994; Duke Power 1999, 2004a) and indicative of no negative impact from MSS operations on Lake Norman fish populations. Spring Electrofishing Surveys Spring electrofishing surveys from 2004 — 2008 were conducted at average water temperatures ranging from 15.6 to 19.4 °C. The number of individuals per 3,000 in ranged from 924 to 2,449 at the MSS area and 1,087 to 2,397 at the REF area (Figure 4-7). Fish biomass per 3,000 in ranged from 68.8 to 142.6 kg at the MSS area and from 69.3 to 114.3 kg at the REF area (Figure 4-8). The number of species per 3,000 in ranged from 16 to 21 at the MSS area and from 17 to 20 at the REF area (Figure 4-9). Previous reports documented that number of individuals, biomass, and number of species collected at the MSS area were generally greater than those from the REF area (Duke Power Company 1994; Duke Power 1999, 2004a). For 2004 — 2008 the number of individuals was generally higher at the REF area, biomass was generally higher at the MSS area, and the number of species varied between areas. The number of individuals in spring electrofishing surveys from 2004 — 2008 was dominated by centrarchids (MSS -90.6%, REF -86.3%), with cyprinids (MSS -6.9%, REF -6.5%) and clupeids (MSS -1.8%, REF -6.4%) greater than 1.0% each, and the remaining families 4-3 representing less than 1.0% of individuals combined (Table 4-2). Pollution tolerant species, mostly redbreast sunfish, represented 18.1% of MSS and 24.2% of REF individuals during spring 2004 — 2008, similar to spring 2000 — 2003 (MSS -15.4%, REF -17.0%). Spring electrofishing survey data varied among years, similar to other Catawba River reservoirs (Duke Power 2004b, 2004c). Fall Hydroacoustics and Purse Seine Surveys Hydroacoustic estimates from 2004 — 2008 showed no temporal trend in annual forage fish populations, ranging from 47.1 to 106.4 million (Figure 4-10). Purse seine surveys from 2004 — 2008 indicate that threadfin shad Dorosoma petenense continue to dominate the Lake Norman forage fish community, comprising 86.6 to 98.3% of fish collected (Table 4-3). Alewife 41osa pseudoharengus, first detected in low numbers in 1999 (Duke Power 2000), have comprised as much as 25.0% (2002) of mid-September pelagic forage fish surveys, but numbers have remained relatively low since 2005 (range = 1.7 — 5.1%). The modal threadfin shad TL class increased after alewife introduction, but has declined and been consistent in recent years. CONCLUSIONS A diverse fish community was present in the littoral portions of Lake Norman around MSS from 2004 — 2008; summer electrofishing surveys documented 20 species (and two centrarchid hybrid combinations). The surveys were numerically dominated by centrarchids and cyprinids, with clupeids also being of numerical importance. Spring electrofishing documented 30 species (and two centrarchid hybrid combinations), dominated by centrarchids and cyprinids. Pollution tolerant species, mostly redbreast sunfish, comprised 18.1% of MSS species and 24.2% of REF species. The assorted fish species typically found in Lake Norman near MSS encompass multiple trophic guilds (i.e., insectivores, omnivores, and piscivores) supporting a balanced fish community. Forage fish population estimates, as measured by hydroacoustics, were variable and ranged from 47.1 to 106.4 million from 2004 — 2008. The estimate range is comparable to those measured previously at Lake Norman with 2008 having the highest estimate since 1997. Purse seine sampling of forage fish indicated a consistent alewife composition of 4-4 approximately 5% after 2004. The introduction of alewife and inherent, temporal fluctuations in clupeid densities contribute to the variable nature of forage fish populations. Past studies have indicated that a balanced indigenous fish community exists near MSS (Duke Power Company 1994; Duke Power 1999, 2004a). The present study adds more years of comparable data, reinforcing that conclusion. Based on the diversity and numbers of individuals in the Lake Norman littoral fish community during spring and summer, the range of trophic groups represented, and the regular availability of forage fish to limnetic predators, it is concluded that the operation of MSS has not impaired the Lake Norman fish community. 4-5 Table 4-1. Number of individuals, percent composition, and number of species in summer electrofishing surveys from five locations (A - E) in Lake Norman, 1991 - 1993, 1994 -1999, 2000 - 2003, and 2004 - 2008. 4-6 Sumner 1991 -1993° Sumter 1994. 19W Sumner 2000 - 2003 Sumner 2004 - 2008 Scientific Nene Comron Nam W. % W. % W. % W. % Lepiscsteidee Lepisosteus osseus Longnose gar 11 0.26% 3 0.09°/6 Clupeidee Al-pseudoharengus Alewife 5 0.16% Dorosoma cepecff- Gizzard shad 11 0.72% 38 0.91% 4 0.19% 6 0.19% Dorosome pefenense Threadfin shad 5 0.33% 355 8.540A 60 1.88% Cyprinldae Carossius auratus Goldfish 1 0.03% Cymnella chtwistia GreeMin shiner 15 0.98% 54 1.30% 28 1.32% 53 1.66% Cyc inella nivea Whdefbr shiner 170 11.10% 469 11.280% 257 1209% 58 1.82% Cypdnus carpi. Comnen carp 53 3.46% 94 226% 11 0.52% 3 0.09% Notemigonus crysoleucas Golden shiner 5 0.12% Notropfs hudsonius Spotted shiner 29 0.70% 157 7.395/6 100 3.14% Nob -pis Procne Swellowtailshiner calostomidae Carpfodes cyprinus Quillback 5 0.12% Moxosfoma macrolepidotum Shorthand redhome 7 0.33% 5 0.16% Moxostoma sp. Brassy jurnprock 6 0.14% letalurldae Ictalur" punctatus Channel catfish 11 0.72% 10 0.24% 4 0.19% 7 0.220% pyfodfcfis olivaris Flathead catfish 16 0.38% 2 0.09% 3 0.09% Poeclllidee Gambusiaholbrooki Eastern rmsqudofsh 5 0.33% Moronidae Moron americana White parch 8 0.38% Moron Chrysops White bass 5 0.12% Conlrarchidee -� Lepomfs ad- Radbreasl sunfish 119 7.77% 261 6.28% 317 14.92% 272 8.53% Lep.W. cyanllua Green sunfish 5 0.33% 1 0.05% 58 1.82% Leponris gibbosus HUmpinlnseed 5 0.33% Lepomis gulosus Warnouth 26 1.70% 91 2.19% 42 1.98% 74 2.32% Lepomis hybrid Hybrid sunfish 5 0.33% 99 2.38% 58 2.73% 53 1.66% Up-rnacnochfrus Bluegid 926 60.44% 1,829 43.98% 900 42.35% 1,957 61.41% Leponds mfcrolophus Rod- sunfish 5 0.33% 71 1.71% 78 3.67% 65 2040% Mbropferus purafulatus Spotted bass 86 270% Micropterus salmoides Largenouth bass 133 8.68% 422 10.15% 240 11.29% 313 9.8204 Micropterus hybrid Hybrid black bass 2 0.06% Pomoxts nigromaculatus Black crappie 6 0.14% 1 0.05% Percidse Etheostoma olmstedi Tessellated darter 20 1.31% 26 0.63% Pence flavescens Yellow perch 18 1.17% 257 6.18% 10 0.47% 3-20 Total No. Individuals 1,532 100.00°/6 4,159 100.00% 2,125 100.00% 3,187 100.ODb/6 Total No. Species 16 21 17 20 • locations B and Ewere not.."pled in 1992, location B was rat sarnpled in 1993 b location B w as not sanpled in 1994, bcatons A and B were not sanplad in 1995 4-6 Table 4-2 Number of individuals, percent composition, and number of species in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 - 1997 and 1999, 2000 - 2003, and 2004 - 2008. Total No. Ind'rviduala 8,599 100.00% 8,970 100.00% 8,878 100.00% 7,390 100.00% 8,386 100.00% 9,631 100.00% Total No. Species 24 21 28 27 28 25 4-7 Spfing 1983 - 1997, 1966 Spring 2000.2003 Spring 2004 - 2008 MSS REF NSS REF MSS Rff Scientific Name Common Name No. % hl . % No. % W. % N . % No. % Lopieoslridaa 2 0.03% 1 0.01% 1 0.01% 1 0.01% Lepisosteus osseus Longnose gar Clupsidae Ala. Be 45 0.51% 57 0.77% 1 0.01% 51 0.53% Alava pseudchareagus 81 0.94% 50 0.72% 30 0.34% 94 1.27% 27 0. 38 0.38% Dorosoma cepedianum Gizzard shad 1,515 21.72% 840 9.46% 58 0.78% 127 7.551%1% 523 5.43% D..- Peter-. Threadfi shad 944 10.98% Salm onidae Oncorhynchw mykiss Rainbow trout 2 0.02% 1 0.01% Cyprinidae Greenfin 22 0.26% 12 0.17% 50 0.56% 153 207% 43 0.51% 38 0.30% Cyprinelle chlorisge Cyprinella nima shiner Whitsfin shiner 734 8.54% SBe 8.40% 1,257 14.16% 1,470 19.89% 228 2.72% 353 3.87% Cyprinus carpio Comron carp 157 1.83% 168 2.41% 190 2.14% 51 0.68% 58 0.69% 48 0.50% Hybognothus regius Eastern silvery rainnow 2 0.02% Nocomis leplocephalus 6tuehead chub 1 0.01% 0.01% Notemigonus crysoleucas Golden shiner 8 0.09% 5 0.07% 4 0.05% 2 0.03% 7 0.08% 1 Natropis hudsonius Spatial shiner 414 4.81% 67 0.98% 472 5.32% 561 7.59% 240 288% 184 1.91% Notropis procne S.alowtalshiner 1 0.01% 1 0.01% R'mephalespromelas Fathead nin- 1 0.01% Catoatcuinl 5 0.06% 0 0.09% 3 0.03% 3 0.04% 2 0.02% 4 0.04% Carpiades cyprinus Guilback 4 0.05% 4 0.05% Moxwtoma macrolepidotum Shorthead redhorse 2 0.02% Ictaluridae 1 0.01% Ictalurus catus While catfish 2 0.02% a0.11% 1 0.01% Ictalurus furcatus Blue catfish Channel 22 0.26% 14 0.20% 37 0.42% 40 0.54% 16 0.19% 24 0.25% Ictalurus punctatus Pyfodictis olivaris cadish Flathead catfish 7 D.08% 4 0.06% 14 0.16% 6 0.08% 9 0.11% 14 0.15% Moronic! a Marone americana While perch 8 0.09% 103 1.16% 4 0.05% 8 0.10% 17 0.18% Me, -Chrysops White bass 6 0.07% 4 0.06% 2 0.02% 3 0.04% Marone sexatilis Striped bass 6 0.07% 3 0.03% 2 0.03% 1 0.01% 1 0.01% Cantrarchidae Lepomis surirus Pedbreast sunfish 1,398 16.26% 1,017 14.58% 957 10.78% 1,004 13.59% 1,110 13.24% 1.925 19.99% Lepomis cyanellus Green sunfish 129 1.64% 12 0.72% Lepomis gibbosus PuMidnseed 4 150 0.05% 1.69% 118 1.60% 111 1.32% 225 234% Lepomis gulwus Warmouth 63 219 0.73% 255% 95 207 1.36% 2.97% 213 240% 197 267% 340 4.05% 380 3.74% Lepomis hybrid ' Hybrid sunfish SluegiL 2,731 31.76% 1.939 27.80% 3,418 38.51% 2.622 35.48% 4,600 54.85% 4,735 49.16% Lepomis macrochims Red 111 1.29% 174 2.49% 468 5.27% 477 6.45% 558 6.67% 558 5.79% Lepomis microlophus -sunfish 15 0.17% 12 0.16% 304 3.63% 188 2.06% Micropterus punctuletus Spotted bass Largemouth bass 1,349 15.69% 911 13.06% 573 6.46% 420 5.68% 408 4.87% 270 2.80% Micropterus Seim oides 19 0.23% 11 0.11% Micropterus hybrid Hybrid black bass Pomoxis annularis White crappie 3 0.03% 1 0.01% 19 0.26% 19 0.23% 22 0.23% Pomoxis nigromaculatus Blackcrappie 51 0.59% 118 1.69% Perot as Ethecare- fusihxme Swamp darter 1 0.01% , Ethewtoma ofMstadi Tessellated darter 1 0.01% 1 0.01% 1 0.07% 3 0.04% 3 0.04% 4 0.04% Pace Bamscens Velow perch 256 2.98% 80 1.15% 17 0.19% 3 0.04% 8 0.10% 13 0.13% Total No. Ind'rviduala 8,599 100.00% 8,970 100.00% 8,878 100.00% 7,390 100.00% 8,386 100.00% 9,631 100.00% Total No. Species 24 21 28 27 28 25 4-7 Table 4-3. Forage fish species composition and modal threadfm shad total length (TL) class in purse seine surveys in Lake Norman, 1993 - 2008. 4-8 Species Composition Modal threadfin shad Year No. Threadfin shad Gizzard shad Alewife TL class (mm) 1993 13,063 100.00% 31-35 1994 1,619 99.94% 0.06% 36-40 1995 4,389 99.95% 0.05% 31-35 1996 4,465 100.00% 41-45 1997 6,711 99.99% 0.01% 41-45 1998 5,723 99.95% 0.05% 41-45 1999 5,404 99.26% 0.26% 0.48% 36-40 2000 4,265 87.40% 0.22% 12.37% 51-55 2001 9,652 76.47% 0.01% 23.52% 56-60 2002 10,134 74.96% 25.04% 41-45 2003 33,660 82.59% 0.14% 17.27% 46-50 2004 21,158 86.55% 0.24% 13.20% 51-55 2005 23,147 98.10% 1.90% 36-45 2006 14,823 94.87% 5.13% 41-45 2007 27,169 98.34% 1.66% 41-45 2008 47,586 95.58% 4.42% 4.1-45 4-8 n— .1. -.1. c Nuclear Station one 2 Figure 4-1. Sampling locations and zones associated with fishery assessments in Lake Norman. 4-9 400 350 E 300 0 250 N Z 200 :w 150 a U 100 50 0 12 10 -n 8 m n fD 6 ! z 0 4 ^� 0 O 2 `- C M p� O O O M O O O O O O O O O O O O O M O O O O O O O O O O O O O O r r r r r r N N N N N N N N N Year Figure 4-2. CPLE and number of fish species in summer electrofishing surveys from Location A in Lake Norman, 1994 — 2008. 400 350 300 0 250 N Z 200 Uj 150 a- () v 100 50 0 12 10 -n Cn 8 a CD n cD 6 ! Z 0 4 N O 0 2 `- A In CO I� 00 O O r N M to O 0 00 O O O O O O O O O O 0 O O O O O M O O O O O O O O O O O O O O r r r r r r N N N N N N N N N Year Figure 4-3. CPUE and number of fish species in summer electrofishing surveys from Location B in Lake Norman, 1994 — 2008. 4-10 400 350 300 0 250 N 0 200 � 150 a U 100 50 0 12 10 -n N S Cn 8 0 co 0 Co 6 Z 0 4 ^� 0 0 3 2 0 d In CO I� W M O r- N M 0 0 t0 0 a0 M O O O O O O O O O Year Figure 4-4. CPUE and number of fish species in summer electrofishing surveys from Location C in Lake Norman, 1994 — 2008. 400 350 300 0 250 N z 200 U' 150 n. v 100 50 0 12 10 -n 0 8 co 0 co' 6 0 z 0 4 N 0 O C 3 d tf) CO f� 00 M O CD N M Ct o0 M M M M M M O O O O O 0 O 0 O 0 O O � M M M M M N N N N N N N N N Year Figure 4-5. CPUE and number of fish species in summer electrofishing surveys from Location D in Lake Norman, 1994 — 2008. 4-11 400 350 300 0 250 N z 200 :w 150 U 100 50 0 IM 10 -n 8 Cn -0 fD 6 w z 0 4 N 0 0 2 '� ;7 O O O O O O O O O O O O O O O Year Figure 4-6. CPUE and number of fish species in summer electrofishing surveys from Location E in Lake Norman, 1994 — 2008. els 3000 2500 E 00 2000 C CO z 1500 L Ll. 1000 500 CO I -T to (O f- O ON M VV) O r- O M O O O O 0) O O O O O O O O O O O O O O m O OO O O O O O O N N N N N N N N N Year Figure 4-7. Number of fish collected in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 —1997, 1999 — 2008. 4-12 200 180 160 140 E 120 0 0 O aS 100 N 80 LL 60 40 20 0 CO V' LD to ti O ON M IT to w r. -O 0') O O Q, p, pO O O O O O O O O O O O O O O O N N N N N N N N N Year Figure 4-8. Biomass of fish collected in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 — 1997, 1999 — 2008. 25 OW: E O 0 X15 0 Z (a ) ca.)) 10 0. U) c U) LL C M d' LO CO r- O O N M It to W L- M CD 0D O O O W O O O O O O O O O O O O O O O N N N N N N N N N Year Figure 4-9. Number of fish species collected in spring electrofishing surveys from two areas (MSS and REF) in Lake Norman, 1993 — 1997, 1999 — 2008. 4-13 120 100 80 N C O E 60 6 Z 40 20 -Zone 1 —Zone 2 -+-Zone 3 —Zone 4 0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 Year Figure 4-10. Zonal and lake -wide population estimates of pelagic forage fish in Lake Norman, 1997 — 2008. 4-14 LITERATURE CITED Brandt, SB. 1996. Acoustic assessment of fish abundance and distribution. Pages 385-432 in BR Murphy and DW Willis, editors. Fisheries Techniques. American Fisheries Society, Bethesda, MD. Brinkhurst, RO. 1974. The Benthos of Lakes. The MacMillan Press, London. 190 pp. Duke Power Company. 1994. Assessment of balanced and indigenous populations in Lake Norman near Marshall Steam Station. Duke Power Company, Charlotte, NC. Duke Power. 1999. Assessment of balanced and indigenous populations in Lake Norman near Marshall Steam Station. Duke Power, Charlotte, NC. Duke Power. 2000. Lake Norman maintenance monitoring program: 1999 summary. Duke Energy Corporation. Charlotte, NC. Duke Power. 2004a. Assessment of balanced and indigenous populations in Lake Norman near Marshall Steam Station. Duke Power, Charlotte, NC. Duke Power. 2004b. Assessment of balanced and indigenous populations in Mountain Island Lake near Riverbend Steam Station. Duke Power, Charlotte, NC. Duke Power. 2004c. Assessment of balanced and indigenous populations in Lake Wylie near Plant Allen. Duke Power, Charlotte, NC. Duke Power. 2005. Lake Norman maintenance monitoring program: 2004 Summary. Duke Energy. 2006. Lake Norman maintenance monitoring program: 2005 Summary. Duke Energy. 2007. Lake Norman maintenance monitoring program: 2006 Summary. Duke Energy. 2008. Lake Norman maintenance monitoring program: 2007 Summary. Hayes, DB, CP Ferrier, and WW Taylor. 1996. Active fish capture methods. Pages 193-220 in BR Murphy and DW Willis, editors. Fisheries Techniques. American Fisheries Society, Bethesda, MD. Mecklenburg County Department of Environmental Protection (MCDEP). 2003.. Lake monitoring data summary for 2001-2002. Charlotte, NC MCDEP. 2007. Lake monitoring report for 2007. Charlotte, NC. Milligan, MR. 1997. Identification manual for the Oligochaeta of Florida. Vol. 1. 187 pp. L-1 North Carolina Department of Environment, and Natural Resources (NCDENR). 2003. Basinwide assessment report; Catawba River Basin. North Carolina Department of Environment and Natural Resources Division of Water Quality. 203pp. NCDENR. 2006. Standard operating procedure. Biological monitoring: stream fish community assessment program. NCDENR, Division of Water Quality, Water Quality Section. Raleigh, NC. NCDENR. 2008. Lake and reservoir assessments; Catawba River Basin. North Carolina Department of Environment and Natural Resources Division of Water Quality. Environmental Sciences Section. 21pp L-2 APPENDIX TABLES Appendix Table A-1. Species composition, number of individuals, number of species, temperature, and dissolved oxygen concentration in July 6, 2004, electrofishing survey from five locations (A — E) near MSS in Lake Norman. Scientific Name Locations A B C D E Total Common Name No. No. No. No. No. No. % Clupeidae Alosa pseudoharengus Alewife 5 5 0.8% Dorosoma petenense Threadfin shad 59 1 60 9.6% Cyprinidae Cyprinella chloristia Greenfin shiner 2 2 0.3% Cyprinella nivea Whitefin shiner 2 2 18 22 3.5% Cyprinus carpio Corrrron carp 1 1 2 0.3% Catostom idae Moxostoma macrolepidotum Shorthead redhorse 1 1 0.2% Ictaluridae Ictalurus punctatus Channel catfish 1 1 1 3 0.5% Pylodictis olivaris Flathead catfish 1 1 0.2% Centrarchidae Lepomis auritus Redbreast sunfish 9 2 9 1 46 67 10.7% Lepomis gulosus Warmouth 1 1 6 4 12 1.9% Lepomis hybrid Hybrid sunfish 5 1 3 9 1.4% Lepomis macrochirus Bluegill 11 58 174 5 105 353 56.6% Lepomis microlophus Redear sunfish 3 2 5 10 1.6% Micropterus salmoides Largemouth bass 9 56 1 8 74 11.9% Percidae Perca flavescens Yellow perch 3 3 0.5% Total No. Individuals 84 80 255 14 191 624 100.0% Total No. Species 7 8 6 7 8 14 Water Temperature (° C) 29.3 29.3 27.4 28.8 28.8 Dissolved Oxygen (mglL) 7.4 6.3 1.9 6.9 7.4 A-1 Appendix Table A-2. Species composition, number of individuals, number of species, temperature, and dissolved oxygen concentration in July 20, 2005, electrofishing survey from five locations (A — E) near MSS in Lake Norman. A-2 Locations A B C D E Total Scientific Name Cormnn Name No. No. No. No. No. No. % Cyprinidae Carassius auratus Goldfish 1 1 0.2% Cyprinella chloristia Greenfin shiner 15 1 16 3.5% Cyprinella nivea Whitefin shiner 1 4 1 6 1.3% Notropis hudsonius Spottail shiner 2 2 0.4% Centrarchidae Lepomis auritus Redbreast sunfish 10 1 7 23 41 8.9% Lepomis gulosus Warmouth 4 7 3 14 3.0% Lepomis hybrid Hybrid sunfish 1 2 3 5 11 2.4% Lepomis macrochirus Bluegill 32 65 85 2 85 269 58.5% Lepomis microlophus Redear sunfish 5 6 8 10 29 6.3% Micropterus punctulatus Spotted bass 2 2 0.4% Micropterus salmoides Largemouth bass 6 6 45 2 10 69 15.0% Total No. Individuals 72 84 155 12 137 460 100.0% Total No. Species 7 5 7 4 6 10 Water Temperature (*C) 31.1 31.0 33.3 30.5 29.7 Dissolved Oxygen (mglL) 8.2 3.7 1.7 6.0 7.9 A-2 Appendix Table A-3. Species composition, number of individuals, number of species, temperature, and dissolved oxygen concentration in July 3, 2006, electrofishing survey from five locations (A — E) near MSS in Lake Norman. Locations A B C D E Total Scientific Name Common Name No. No. No. No. No. No. % Le pisoste idae Lepisosteus osseus Longnose gar 1 1 0.1% Clupeidae Dorosoma cepedianum Gizzard shad 2 2 0.3% Cyprinidae Cyprinella nivea Whitefin shiner 3 4 7 0.9% Catostom idae Moxostoma macrolepidotum Shorthead redhorse 3 1 4 0.5% Ictaluridae ktalurus punctatus Channel catfish 1 2 3 0.4% Centrarchidae Lepomis auritus Redbreast sunfish 20 1 18 6 51 96 12.9% Lepomis cyanellus Green sunfish 5 6 1 12 1.6% Lepomis gulosus Warmouth 3 26 29 3.9% Lepomis hybrid Hybrid sunfish 2 4 7 13 1.7% r--, Lepomis macrochirus Bluegill 40 96 196 112 98 542 72.7% Lepomis microlophus Redear sunfish 1 5 1 2 4 13 1.7% Micropterus punctulatus Spotted bass 2 3 5 0.7% Micropterus salmoides Largemouth bass 3 3 12 18 2.4% Micropterus hybrid Hybrid black bass 1 1 0.1% Total No. Individuals 75 105 233 130 203 746 100.0% Total No. Species 8 4 8 6 7 12 Water Temperature (° C) 29.5 31.3 32.7 29.8 30.1 Dissolved Oxygen (mg/L) 8.4 3.7 1.9 7.6 8.5 A-3 J �— Appendix Table A-4. Species composition, number of individuals, number of species, temperature, and dissolved oxygen concentration in July 10, 2007, electrofishing survey from five locations (A — E) near MSS in Lake Norman. Locations A B C D E Total Scientific Name Common Name No. W. No. W. No. No. % Clupeidae Dorosoma cepedianum Gizzard shad 1 1 0.2% Cyprinidae Cyprinella chloristia Greenfin shiner 10 4 14 3.1% Cyprinella nivea Whitefin shiner 3 3 6 1.3% Ictaluridae Pylodictis olivaris Flathead catfish 2 2 0.4% Centrarchidae Lepomis auritus Redbreast sunfish 20 2 4 9 35 7.6% Lepomis cyanellus Green sunfish 17 1 7 25 5.4% Lepomis gulosus Warmouth 2 1 3 0.7% Lepomis hybrid Hybrid sunfish 3 1 1 4 9 2.0% Lepomis macrochirus Bluegill 16 56 167 8 52 299 65.1% Lepomis microlophus Redear sunfish 1 1 2 0.4% — Micropterus punctulatus Spotted bass 5 1 1 7 1.5% 1 Micropterus salmoides Largemouth bass 4 9 34 1 7 55 12.0% Micropterus hybrid Hybrid black bass 1 1 0.2% Total No. Individuals 82 70 217 10 80 459 100.0% Total No. Species 10 6 6 2 6 11 Water Temperature ('C) 31.7 30.0 24.7 292 28.4 Dissolved Oxygen (mg1L) 8.4 2.8 1.3 6.8 7.8 A-4 Appendix Table A-5. Species composition, number of individuals, number of species, temperature, and dissolved oxygen concentration in July 9, 2008, electrofishing survey from five locations (A — E) near MSS in Lake Norman. Locations A B C D E Total Scientific Name Common Name No. No. No. No. No. No. % Le pisoste idae Lepisosteus osseus Longnose gar 2 2 0.2% Clupeidae Dorosoma cepedianum Gizzard shad 3 3 0.3% Cyprinidae Cyprinella chloristia Greenfin shiner 14 7 21 2.3% Cyprinella nivea Whitefin shiner 2 5 10 17 1.9% Cyprinus carpio Common carp 1 1 0.1% Notropis hudsonius Spottail shiner 94 4 98 10.9% Ictaluridae Ictalurus punctatus Channel catfish 1 1 0.1% Pylodictis olivaris Flathead catfish Ce ntrarchidae Lepomis auritus Redbreast sunfish 15 3 15 33 3.7% Lepomis cyanellus Green sunfish 7 5 5 3 1 21 2.3% Lepomis gulosus Warmouth 2 4 7 3 16 1.8% Lepomis hybrid Hybrid sunfish 1 3 2 5 11 1.2% Lepomis macrochirus Bluegill 19 122 124 31 198 494 55.0% Lepomis microlophus Redear sunfish 7 2 2 11 1.2% Micropterus punctulatus Spotted bass 18 24 1 19 10 72 8.0% Micropterus salmoides Largemouth bass 11 12 53 13 8 97 10.8% Total No. Individuals 74 179 195 186 264 898 100.0% Total No. Species 7 8 6 9 11 14 Water Temperature (° C) 28.8 30.9 33.6 28.3 27.6 Dissolved Oxygen (mg/L) 7.7 2.6 1.2 6.3 7.1