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Home My WebLink About20030147 Ver 2_WRC Comments_20170306Strickland, Bev From: Goudreau, Chris J. Sent: Monday, March 06, 2017 1:41 PM To: Stuart, Alan Witten; John Ellis; Fritz Rohde (Fritz.Rohde@noaa.gov); Bill Marshall (marshallb@dnr.sc.gov); Tracy, Bryn Cc: Higgins, Karen; Tarver, Fred; Styer, Tami; Abney, Michael A; Brown, Jason S; Dycus, Justin C Subject: RE: Draft 2016 Aquatic Life Monitoirng Plan Report for review Attachments: 2017-02-17 ALMP report - Draft - WRC edits.docx See attached for my edits. From: Stuart, Alan Witten [mailto:Alan.Stuart@duke-energy.com] Sent: Friday, February 17, 2017 12:57 PM To: John Ellis <John_Ellis@fws.gov>; Goudreau, Chris J. <chris.goudreau@ncwildlife.org>; Fritz Rohde (Fritz. Rohde@noaa.gov) <Fritz.Rohde@noaa.gov>; Bill Marshall (marshal lb@dnr.sc.gov) <marshalIb@dnr.sc.gov>; Tracy, Bryn <bryn.tracy@ncdenr.gov> Cc: Higgins, Karen <karen.higgins@ncdenr.gov>; Tarver, Fred <fred.tarver@ncdenr.gov>; Styer, Tami <Tami.Styer@duke- energy.com>; Abney, Michael A <Michael.Abney@duke-energy.com>; Brown, Jason S <Jason.Brown2@duke- energy.com>; Dycus, Justin C <Justin.Dycus@duke-energy.com> Subject: Draft 2016 Aquatic Life Monitoirng Plan Report for review Good afternoon Aquatic Life Monitoring Team Members (ALMT), Attached for your review, is the 2016 Aquatic Life Monitoring Program Draft Report prepared by Duke Energy. This monitoring program is required by Section 7 of the 401 Water Quality Certification and Article 401 of the New License. The attached draft report provides information relative to the first year of monitoring below our Tillery Hydrostation as described in the ALMT and FERC approved study plan. Please review the attached report and provide us any comments by March 17, 2017. This will allow us time to address any comments received and file, as required, with FERC by March 31, 2017. We appreciate all of you working with us to meet our License requirements and if you have questions please let us know. Have a great weekend and thank you ! Alan Alan W. Stuart Senior Project Manager Duke Energy Carolinas, LLC Water Strategy, Hydro Licensing and Lake Services 526 S. Church Street, - EC12Y I Charlotte, NC 28202 Office 980-373-2079 1 Cell 803-640-8765 Email correspondence to and from this sender is subject to the N.C. Public Records Law and may be disclosed to third parties. Yadkin -Pee Dee Hydroelectric Project FERC No. 2206 201E Aquatic Life Mont oring iqn%hte Pee Dee Rives Below The Tille elect lant ue'ecea:q Duke Energy Environmental Services fa DUKE ENERGY 2017 Table of Contents Table of Contents Formatted: Font color: Auto Section Page List of Tables ii List of Figures iii Executive Summary iv 1.0 Introduction 1-1 2.0 Monitoring Site Description 2-1 3.0 Monitoring Methods 3-1 3.1 Benthic Macroinvertebrate CoMonitoring 3-1 m;3 -2 u 3.2 Fish Community Monitoring 3.3 Other Environmental Measuremen 3-7 4.0 Monitoring Results 4-1 4.1 Benthic Macroinvertebrate Community Resu 4-1 4.2 Fish Comm ity Results 4-1 4.3 Environmental Results 4-10 5.0 Discussion 5-1 5.1 Benthic Macroinvertebr 5-1 52 ish Community 5-1 5.3 Environmental 5-2 6.0 eferences 6-1 Formatted: Font color: Auto APPENDICES APPENDIX A - DAILY A RAGE DISSOLVED OXYGEN, MINIMUM DISSOLVED OXYGEN AND DAILY MINIMUM FLOW COLLECTED NEAR TZ I (USGS GAGING STATION NO. 0212378405 AT HWY 731 BRIDGE) AND AT TZ2 FROM MAY 1 —NOVEMBER 30, 2008 AND 2016 Formatted: Fant calor: Auto ------------------------------------------------------------- APPENDIX B - TAXONOMIC LISTING OF BENTHIC MACROINVERTEBRATES COLLECTED FROM SITES TZ1 AND TZ2 IN THE PEE DEE RIVER BELOW TILLERY DAM DURING JULY 2008 AND JULY 2016 AND THE TAXON'S ASSOCIATED BIOTIC INDEX TOLERANCE VALUE (T.V.)'. List of Tables List of Tables Table Page 2-1 Geographical Positioning System locations, channel widths and habitat characteristics of sampling Sites used in the aquatic life monitoring plan belowthe Tillery Dam--------------------------------------------------------------------------------------------2-2 4-1 Total and EPT richness/abundance scoring metrics for Sites TZ1 and TZ2 in the Pee Dee River below Tillery Dam d;r 2008 and July 2016 ......... 4-1, , - Formatted: Font color: Auto 4-2 Tolerance value, trophic status and number of fish collected from Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016 ................4-3 4-3 Catch rates (fish/hour) for electrofishing samples (pram and backpack) collected at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016---------------------------------------- lhh 44 s------p-r-am- Biomass collection r (grams/hour) m44 efes and backpack) collected at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016 ...................................... ------ --------------------------------------4-5 4-5 Catch rates (fish/haul) for seine hauls collected at TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016 .. ..................................... 4-6 4-6<Characteristics omasNco ction rates (grams/haul) for seine hauls collected at Sites 1 and TZ2 below Tillery Dam during August 2008 and July 2016 .. ............. 4-6 4-7 of the fish community below the Tillery Dam at Sites 1 and TZ2 during 2008 and 2016.....................................................................4-7 4-8 Individual lengths (1 specimen collected), mean lengths (total length, mm) and size ranges (minimum and maximum) of fish collected below Tillery Dam du - 2 d 2016------------------------------------------------------------------------------------4-9 4-9 Variances from NC 401 WQ Certificate for the monitoring period May 1 — November 30 (NA — Not Applicable).................................................. 4-11 4-10 Temperature, dissolved oxygen, specific conductance, pH, and turbidity values collected during the macroinvertebrate and fish community assessment below Tillery Dam during 2016 . ...................................................... 4-12 List of Figures List of Figures Fi ure Page 2-1 Aquatic life monitoring sample Sites (TZ1 and TZ2) on the Pee Dee River below the Tillery Development ............................. 2-1 4-2 Dissolved oxygen levels collected every 15 mi from May 1 through November 30, 2016 near TZ 1 ........................ .................................4 -15 4-3 Dissolved oxygen levels collected every 15 minuteifrom May 1 through .. ...............................4-16 Formatted: Font color: Auto Executive Summary Executive Summary On September 30, 2008, Duke Energy Progress, LLC (Duke Energy) received a 401 Water Quality Certificate (WQC; No. 3730, MOD 1) from the NC Division of Water Resources (NCDWR) as required by the relicensing of the Yadkin -Pee Dee Hydroelectric Project for the Blewett Falls and Tillery Developments (Project No. 2206). The 401 WQC was incorporated__ , - Formatted: Fant calor: Auto into the New License issued by the Federal Energy Regulatory Commission (FERC 2015) to Duke Energy on April 1, 2015. Section 7 of the WQC requires Duke Energy to c nduct aquatic life monitoring in the Pee Dee River below the Tillery Development. _The Aqu ife Monitoring Plan was submitted to the FERC on December 8, 2015, and approved on uary 6,)01 FERC 2016). Two sites (TZ1 and TZ2) within an eight kilometer (km) reach from the Tillery to the confluence of the Rocky River were monitored in accordance with the plan. This re ort documents the condition of the aquatic communitoWsh and macroinvertebrates) post imp mentation of the new terms and conditions outlined in the 401 WQC compared to the baseline assessment of the aquatic community that existed prior to the implementation of the 401 WQC, , - Formatted: Font color: Auto In 2016, a total of 76 macroinvertebrate taxa were collecte4t Site TZ1, and a total of 60 macroinvertebrate taxa were collected at Site TZ2. The bioclassification scores for Site TZ1 and TZ2 were Good -Fair in 2016. A total of 347 fish representing 17 taxa were collected at Site TZ1, and of 237 fish representing 16 taxa were collected from Site TZ2. The fish comm at Site TZ1 consists primarily of N American catfish and minnow species_ The , - Deleted: fish co unity at Site T consists%Oisease, rily of North American catfish, sunfish and darter species. There were no fish with signfin erosion, lesions or tumors, and only a low number of Green Sun sh prese Site TZ2 (signs of environmental stressors). Formatted: Font color: Auto -------------------------------- iv Introduction 1.0 Introduction On September 30, 2008, Duke Energy received a 401 Water Quality Certificate (WQC; No. 3730, MOD 1) from the NC Division of Water Resources (NCDWR) as required by the relicensing of the Yadkin -Pee Dee Hydroelectric Project for the Blewett Falls and Tillery Developments (Project No. 2206). The 401 WQC was incorporated into the New License issued by the FERC to Duke Energy on April 1, 2015. The New License required Duke Energy to develop an Aquatic Life Monitoring Plan (ALMP) in consultation with the following resource agencies: North Carolina Wildlife Resources Commission (NCWRC), South Carolina Departme of Natural Resources (SCDNR), North Carolina Division of Water Resources (NCDWR), 'sh and Wildlife Service , - ueleted: de SFWS d National Marine Fisheries Service FS The res agencies along with , -(Deleted: de (U ), u� -tonal Ma --------------(NM- )_ - -- Duke Energy comprise the Aquatic Life Monitorin Team (rranuary T). The was submitted to FERC for approval on December,8, 2015 and approved on 6, 2016 C 2016). For Fant calor: auto The ALMP requires Duke Energy to conduct aquatic 1 e monitoring in the Pee Dee River below the Tillery Development to do nt the condition aquatic community on three year intervals for at least four cycles (i.e., 16, 2019, 2022, and 2025) ending in 20251. Two sites (TZ1 and TZ2, Figure 2-1)'•within an eight_km rea4,from the Tillery Dam to the ,- Deleted: confluence of the Rocky River weream 1 to -document-the _condition of _the aquatic__ , - Deleted: monitored community following the implementation the solved oxygen (DO) and instream flow requirements of the New License. This documents the condition of the aquatic community (fish and macroinvertebrate) during the first monitoring year post license implementation (i.e., 2016) and compares the results to the baseline assessment conducted in 2008. After the fo monitoring cycle (i.e., 2025) a determination will be made by the ALMT as to whether the Ne ense rgquirements have contributed to an improvement in the aquatic community or whether o environmental factors (e.g., nonnative species competition and predation, basin wide sedimentation or other water quality issues) are affecting the community. A bioclassification ranking of "Good -Fair" will be considered the minimum threshold in 1 The 401 WQC defines the final sampling period occurring in year 2020. This date anticipated issuance of the New License prior to 2015. Therefore, monitoring on three-year intervals for at least four cycles would extend the last monitoring period to 2025. M Introduction assessing a positive response of the benthic community to flow and DO improvements implemented during the New License term. Fish and benthic macroinvertebrate communities were assessed in accordance with the ALMP (Duke Energy 2015). Biotic indices, derived from standardized benthic macroinvertebrate,collections, and selective fish community metrics will be used in assessing ------ Deleted: s any changes in the environmental quality in this reach of the Pee Dee River. These indices provide a holistic approach to community health assessment by integrating various ecological 0 principles associated with organism and community response to environmental degradations (e.g., reduced species diversity, dominance by tolerant species and reduced population size; Gray 1989, Karr 1981, 1991). Formatted: Fant calor: Auto 1-2 Site Description 2.0 Monitoring Site Description Aquatic life monitoring was conducted at two sites (Sites TZI and TZ2) located in the eight -cm reach of the Pee Dee River below the Tillery Development (Figure 2-1). The length of Deleted: ------------------------------ each monitoring site was approximately 366 meters (m). Formatted: Fant calor: Auto Formatted: Font color: Auto 1 WER F2 N Site T 0 a 1% : A� Site TZ2 44 Figure 2-1 Aquatic life monitoring sampling sites (TZ1 and TZ2) on the Pee Dee River below the Tillery Development. 2-1 Site Description Site TZ1 is located approximately 2.4 km below the Tillery Development, immediately downstream of NC Highway 731 Bridge (Figure 2-1). This upstream site is a shoal with shallow runs with bedrock outcrops, boulders, cobble intermixed with gravel and sand, and cobble and gravel bars present with some sand and silt deposition. Woody debris and rooted aquatic vegetation (Hydrilla sp., Podostemum sp., Potamogeton sp., and filamentous algae) are prevalent at this site (Table 2-1). The downstream Site, TZ2, located approximately 7.2 km downstream of the Tillery i Development and just above the Rocky River confluence, also contains shoal and shallow run habitat (Figure 2-1). The substrate consists of bedrock outcrops and boulder, cobble intermixed with gravel and sand, and cobble/gravel/sand bars. Sand and some silt deposition occur along channel margins (Table 2-1). Woody de d rooted aquatic vegetation (Hydrilla sp., Podostemum sp. and filamentous algae) are pre tat this si e. Formatted: Font color: Auto Table 2-1 Geographical Positioning System (GPS) locations, channel widths, and habitat characteristics of sample sites used in the aquatic life monitoring plan below the Tillery Dam. Vk -%&w 'R& Transect GPS Latitude and Longitude Channel Width (m) Habitat Description TZ1 hoal with bedrock outcrops, boulders, cobble Nermixed Shoal below with gravel and sand, and cobble and Tillery 35.198639 :200Svel bars present with some sand and silt deposition. Development -80.061311 oody debris and rooted aquatic vegetation (Hydrilla and NC sp., Podostemum sp., Potamogeton sp. and Highway filamentous algae) were prevalent. 731 Shoal with prehistoric fishing weir. Bedrock outcrops TZ2 and boulders, cobble intermixed with gravel and sand, 35.151589 170 and cobble/ gravel/sand bars present. Sand and some Shoal above 80.070642 silt deposition noted along channel margins. Woody Rocky River debris and rooted aquatic vegetation (Hydrilla sp., confluence Podostemum sp. and filamentous algae) were prevalent. 2-2 Monitoring Methods 3.0 Monitoring Methods 3.1 Benthic Macroinverteb rate Community Monitoring Benthic macroinvertebrate monitoring was conducted using the NC Department of Environmental Quality (DEQ) Standard Qualitative Method (SQM) for benthic macroinvertebrates (NCDEQ 2016). Ten qualitative samples were collected during each sampling event. The bioassessment and rating of the general environmental quality of the river is based upon benthic community structure attributes whic ude: total number of species, number of mayfly, stonefly, and caddisfly taxa and species tolerance values. Habitat Microhabitat Sample Method Number of Samples Type of Sample Coarse -mesh 500-1000 m High current with structure Riffles Kick net IN 2 Single, disturbance Low current with structure Banks Dip net 3 Composite, disturbance Leaves Leafpacks Wash bucket 1 Composite, wash Fine -mesh (300 m) Aufwuchs Rock and logs U.S. Standard Sieve Size No. 50 2 Composite, wash Sand and U.S. Standard Sieve Size No. 50 1 Composite (3), disturbance Visual Collections Large rock and logs (10-15 Wes) 1 1 Composite Samples were sorted in the field usin tandard Sieve Size No. 50, a white enamel pan and a winnowing technique.anisms were preserved in 95% denatured -ethanol and VIFreturned to the laboratory 1`0identific to the lowest practical taxa level using standard taxonomic references and enumeration. A voucher and reference collection was established for each sampling location to validate taxonomic identification. Numerical abundance for each taxon was tabulated as Rare = 1 (1-2 specimens), Common = 3 (3-9 specimens), and Abundant = 10 (10 + specimens). Pollution tolerance values (T.V.) for each taxon was assigned based on criteria in NCDEQ Benthic IBI SOP (NCDEQ 2016). If an individual species does not have a T.V., but there was a T.V. for the genus level, then the genus level T.V. was used. 3-1 Deleted: Monitoring Methods • The Biotic Index (BI) for each sample was calculated as: I = Es n; * a;/N I Commented [CG1]: Use equation tool where N is the total number of individuals in the sample, ni is the number of (Insert/Equation). individuals in the ith species (taxon), ai is the pollution tolerance value for the ith species, and S is the total number of species. The BI Value and the EPT Value (the number of Epe eroptera [mayflies], Plecoptera [stoneflies], and Trichoptera [caddisflies] taxon) was assigned a score based on the expected score from the Piedmont Ecoregion as developed by the NCDEQ Benthic IBI SOP (NCDEQ 2016). No seasonal correction values were applied to these data as the sampling occurred during the summer months. The two indices (matrices) for each sample were averaged (with scores rounded upward) to produce the final numerical r50if e NCDEQ specified numerical rounding approach was applied to e resulting BI he scores differ by exactly one bioclassification. Bioclassification for each sample (site) was based on the final ranking: Excellent = 5, Good = 4, Good -Fair = 3, Fair = 2 and Poor = 1. There have been multiple taxonomic and T.V. revisions since the 2008 baseline study was originally produced. All 2008 scores were calculated using the NCDWQ (2006) benthic IBI SOP, however, all benthic taxonomic SOP values presented in this report (i.e., tolerance values and scoring criteria), will use the NCDEQ 2016 Version 5.0 Benthic SOP values. All taxonomic , - commented [CG2]: so, are you comparing apples and oranges? Or did you recalculate 2008 using 2016 SOPS? identifications made for the benthic community this report were provided by Pennington and Associates, LLC. Pennington and Associates is an approved vendor for macroinvertebrate identifications as certified byCDEQ 3.2 Fish Comm itoring Fish community sampling efforts followed methods established for the shallow water study conducted during relicensing in 2004 (Progress Energy 2006b). Sampling gear types include: Smith -Root 5.0 GPP pram electrofisher, Midwest Lake Electrofishing Systems Infinity Xstream backpack electrofisher2 and a flat seine (61-m x 1.8-m with 0.32 cm mesh). The pram electrofisher was used to sample the wadeable, mid -channel by making 4 single 15.7;,ninute pass Z A Smith -Root Model 15 backpack electrofisher was used during the 2008 study. 3-2 Commented [CG3]: Unclear. Was the effort 15 minutes in each transect (i.e., a total of 45 minutes) or 15 minutes total (i.e., 5 minutes in each transect)? Since you report the actual effort was over 1 hour, does this mean the 15 -minute pass was the minimum amount of time for each transect? If so, then you might say here that "the minimum targeted effort for each transect was 15 minutes." Monitoring Methods through three linear transects within Site TZ1 and TZ2. The backpack electrofisher was used to sample each river bank, including any backwater areas, by making � single 151ninute Pass - - Commented [CG4]: Ditto. through three linear transects withinSite TZ1 and TZ2.Twelve seine hauls i.e., one haul per Deleted. -------------------------� -- p- -- Deleted: 30.5 in of transect length) were made at sand, gravel, or cobble bars or riffles at each site with all collected Qrganisms combined into one common sample._ For electrofishing sampling, pulsed_- - - Deleted: s ples DC current was used, with the voltage adjusted to produce 3-4 amps in the sampling field (depending upon the water conductivity). Riffle areas were sampled intensively with the pram electrofisher by disturbing the substrate and holding dip nets on the downstream end of the riffle while electrofishing was performed. The total time was recorded for backpack and pram electrofishing, and the catch rates calculated in number and'weight of fish per hour. All electrofishing and seine samples were combined at each site to yie e total number of fish collected per sample site. In addition, catch -per-unit effort (C UE) data were calculated for both electrofishers and seine hauls. Nu ically abundant species within the fis unity were defined as species or taxa comprising > 5% othe total fish abundance at each transect. All fish were identified to the lowest practicable taxa level. Fish were measured for total length to the nearest millimeter (mm) and weighed to the nearest gram (g). Fish not identified in the field were preserved with 10% .buffered formalin solution and transported to the laboratory for identification ands body measurement. A er collected fish were released alive to the sampling site. Fish were retained as nec ssary voucher purposes in Duke Energy's fish reference collection. A modified North Carolina Index of Biotic Integrity (NCIBI) fish community metric was applied to these data to gain insight of the fish community structure at each sampling site. The collected fish specimens were assigned tolerance and trophic feeding guild classifications based on designations used by the NCDWR for its NCIBI methodology (NCDWR 2013). The NCIBI is derived from the Index of Biotic Integrity originally formulated by Karr (1981) to measure the health and structure of stream fish communities. As discussed in the Study Plan for Aquatic Life Monitoring (approved by FERC January 6, 2016), the fish community data cannot be quantitatively scored with the NCIBI (i.e., numeric score with corresponding community health rating). The scoring methodology is based upon wadeable streams and has not been applied to large river systems, such as the Pee Dee River, with the specific array of sampling gear types and lack of comparable reference sites in this study 3-3 Monitoring Methods (NCDWR 2013). Neither reference condition nor accepted sampling methodologies have been established to apply the NCIBI in large river systems. Therefore, as agreed to by the ALMT, there will be no strict success criteria for judging the health of the fish community under this monitoring program (Duke Energy 2015). Three other attributes applied to these data (also approved by the ALMT) are the number of minnows (Cyprinidae), the number of North American catfish species, and the percentage of Green Sunfish. Young -of -year fish were included inthe ulation of all Fish_ community_ , - Deleted: of the attributes listed below. The significance of each fish community metric or attribute is given below, as defined in NCDWR (2013): 1. Number of taxa or species richness: The total number of species supported by a stream of a given size within a given region generally decreases wit environmental degradation. In addition, some streams with larger watersheds or drainage areas can be expected to support more species than streams with smaller watersheds. In other instances, the number of species and watershed size are not correlated. 2. Number of individuals 0 e total number of fish supported by a stream of a given size in a given region decreases with environmental degradation. However, in some instances, nutrient enrichment or degradation may actually increase the number of fish supported by a stream. 3. Numbe of darter species (Etheosa and Percina species): Darters are sensitive to environmental degradation particularly as a realt4f their specific reproductive and habitat requirements. Darter habitats (e.g. e habitat) are degraded as a result of channelization, siltation, reduced oxygen levels, and ating water levels. The collection of fewer than expected number of species of darters can indicate some degree of habitat degradation. 4. Number of minnow species: Many species of minnows are intolerant of habitat and chemical degradation. Because'of their predominantly specialized insectivorous feeding habits, they also reflect the condition of the benthic community which may be harmed by sedimentation, sediment contamination, or varying water levels. Minnow species also typically inhabit shallow water habitats such as stream channel margins which can be affected by fluctuating water levels in regulated streams (Bain and Travnichek 1996). 5. Number of North American catfish species: The number of North American catfish species can provide insight into general environmental conditions present in a stream. Many 3-4 Monitoring Methods North American catfishes are omnivorous feeding generalists tolerant of a wide range of environmental conditions. Conversely, madtom species inhabit shallow water areas and are insectivorous in feeding habits and generally reflect favorable stream environmental conditions. This attribute is not used in the NCIBI but used in this assessment to characterize the entire fish community present in the Pee Dee River. 6. Number of sucker species (includes all species within Catostomidae Family): Many suckers (especially Moxostoma and Scartomyzon species) are intolerant of habitat and chemical i degradation, and because they are long-lived, provide a multiyear integrated perspective. They also reflect the condition of the benthic community which may be affected by sedimentation, sediment contamination, or flow fluctuations. 14 N 7. Number of sunfish species (includes Lepomis, Enneacanthus, opterus, and Pomoxis species): Sunfish species are particularly resp sive to habit degradation such as the filling in of pools with sediment and loss of stream cover (e.g., woody debris). Conversely, most sunfish species (e.g., Bluegill, Redbreast Sunfish, and Largemouth Bass) are habitat and feeding IhZ generalists and show less sensitivityo flow fluctuationIthat other species who are more specialized in feeding or inhabit,,,channel margin habitat (Bain and Travnichek 1996). 8. Number of intolerant species: Intolerant species are those specialized habitat and feeding species most affected by environmental perturbations, and therefore should disappear, at least as viable populations by the time a stream degrade*"Fair". Intolerant species includes some species with a very restricted zoogeogra hp is distribution or considered rare, threatened, or endangere Of the 223 described spe 'es of freshwater fish in NC waters, only 55 species are considered intolerant. 1% 9. Percent tolerant individuals: Tolerant species are those which are often present in a stream in low or moderate numbers but as the stream degrades, they can become dominant (generally greater than 25-35% of the fiscommunity). Of the 223 described species of freshwater fish found in North Carolina, 22 species are tolerant. The metric is calculated by the total number of individuals of tolerant species divided by the total number of collected fish. 10. Percent omnivores and herbivores: Omnivorous feeding species generally indicate degraded environmental conditions. Additionally, large numbers of herbivores can indicate canopy or riparian removal or modifications and/or nutrient enrichment with subsequent increased growth of attached algae and periphyton. 3-5 Monitoring Methods 11. Percent piscivores: Piscivorous feeding species represent the top of the food chain within the aquatic community and their presence usually indicates a healthy, functioning food chain. However, a very large percentage of piscivorous species or the complete absence of predators may indicate environmental perturbations or some other influencing factor. 12. Percent insectivores: Insectivorous feeding species, particularly those that specialize on the benthic invertebrate community (i.e., many minnow, sucker, and darter taxa) generally reflect a healthy river ecosystem. The presence of a large percentage of generalist insectivorous feeding species, particularly those that can feed on a variety of aquatic and terrestrial invertebrates, (e.g., Redbreast Sunfish and Bluegill) can indicate degraded environmental conditions and nutrient enrichment. 13. Percent Green Sunfish: The percentage of Green Sunfish, rant species, typically increases with degraded environmental conditions (i.e., gen ally > 50o otal fish collected would be considered unbalanced; Karr et. al 1986). This attribute is not inc in the NCIBI but used in this assessment to aid in charac erization of the fish community and environmental conditions. 14. Percentage of species with multiple age groups: This metric or attribute provides an indication of reprosuccess and survivabili of year classes through time. It also provides an indirect in iive or of suitable habitat for reproduction and rearing of young. At least three individuals per species must have been collected to determine the presence of multiple age groups within the population. In some nstances, Afessional judgment may also be used to determine reproductive success of a part'cular species. 15. Number nonnative species a ercentage of nonnative species to native species: Nonnative species are currently prevalent in the Pee Dee River below the Tillery Development, especially Smallmouth Buffalo. The presence of nonnative species can negatively affect native species abundance and popula{on response due to predation, competition, or both factors interacting together. This attribute is not included in the NCIBI but is included in this fish community monitoring because of the large presence of nonnative species in the Pee Dee River. Native status is determined with NCDWR guidance. 16. The percentage of fish with disease, fin erosion, lesions, or tumors: This attribute provides insight into existing environmental conditions or stressors that may be contributing to the overall health of each fish species and the fish community as a whole. 3-6 Monitoring Methods 3.3 Other Environmental Measurements During each sampling event, in-situ water temperature, DO, pH, conductivity, and turbidity were measured with a laboratory and field -calibrated YSI® multi -parameter instrument. Sample sites were recorded with a GPS unit to sub -meter accuracy (Table 2-1). Continuous water quality monitoring sondes were deployed near both sites to measure water temperature and DO conditions during the period of summertime reservoir stratification (May through November). Temperature and DO were collected near TZ1 at the N.C. Hwy 731 Bridge United States Geological Survey (USGS) Gaging Station No. 0212378405. At site TZ2, a HOBO DO Data Logger -U26-001 was deployed and rotategout every two weeks. Gaging Station No. 0212378405 was calibrated by USGS staff, while operational checks were performed for each HOBO data logger before each deployment. Streamflow and gage height were also measured by the USGS stream gage near TZ1. These para sand existing conditions aid in evaluating the overall health and of the aquat unity at the sites. 3-7 Results 4.0 Monitoring Results 4.1 Benthic Macroinverteb rates Community Results The benthic macroinvertebrate community was sampled on July 6 (Site TZ I) and July 7 (Site TZ2), 2016 under the License -required minimum flow of 330 cubic_feetper second (cfs)._ - - Deleted: esta6fished A total of 76 taxa were collected at Site TZ1 and a total of 60 taxa were collected at Site TZ2 (Appendix B). EPT taxa represented 29% (n = 22) and 37% (n = 11) of the macroinvertebrates collected at sites TZ1 and TZ2, respectively. Site TZ1 scored 314 (EPT Score), 3.0 (BI Score) and 3.2 (Site Score) with an overall bioclassificatio411 Good -Fair. Site TZ2,scored 3.4 (EPT_ - - Deleted: Score), 3.0 (BI Score) and 3.2 (Site Score) with ani bioclassification of Good -Fair (Table 4-1). fr Table 4-1 Total and EPT richness/abundance scoring metri\an 1 and TZ2 in the Pee Dee River b w Tillery D during July 2016. 1 TZ2 Richness/Abundance 2008 6 2008 2016 Total taxa richness 46 56 60 EPT richness11 2 14 22 EPT abundance ` 51 85 69 91 Biotic Index 6.8 6.1 6.4 6 Scoring EPT score 2.4 3.4 BIsco 2 3 3 3 Sitescore 2 3.2 2.6 3.2 Bioclassification Fair Good -Far Good -Far Good -Fair 4.2 Fish Community Results The fish community was sampled on July 12 (Site TZ2) and July 13 (Site TZ1) 2016. Sampling effort at Site TZ1 cofisisted of 2.45 electrofishing hours (pram (1.35) and backpack (1.10)) and 12 seine hauls. Sampling effort at Site TZ2 consisted of 2.50 electrofishing hours (pram (0.98) and backpack (1.52)) and 12 seine hauls. Previously, Site TZ2 and TZ1 were sampled August 1 and 2, 2008 for 3.37 and 3.5 hours, respectively (Duke Energy 2014). A total of 347 and 237 fish representing 17 and 16 taxa were collected from Sites TZ1 and TZ2 during 2016, respectively (Table 4-2). No rare, threatened or endangered fish species 4-1 Results have been collected to date. Catch rates (fish/hour) and biomass rates (grams/hour) varied by year and site (Tables 4-3 and 4-4). ------------------------------------------------------------ Table 4-2 Tolerance value, trophic status and number of fish collected from Pee Dee River at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016. 4-2 Commented [CGS]: Use a page break if you want table to start on a new page, instead of lots of paragraphs. Deleted: ¶ Results 4-3 Number Collected Number Collected TZl TZ2 Scientific Name Common Name Tolerance Trophic Status 2008 2016 2008 2016 Lepisosteidae Gars 1 Lepisosteus osseus Longnose Gar Tolerant Piscivore - - 1 - Anguillidae fteshwater eels - - I - - Anguillamstroto American Eel Intermediate Piscivore 14 1 4 - Catostomidae Suckers 1 I Erimyzon oblongus Creek Chubsucker Intermediate Onnrivore - - I 1 - ktiobus bubolus Sn"Iniouth Buffalo Intemmediate Onnrivore - 2 1 - - I _ Moxostomomocrolepidotum Shorthead Redhorse Intermediate Insectivore Affik - 1 1 - - Smrtomyzon sp. "Brassy" Jumprock Intermediate Insectivore AWFI- I Clupeidae Shad ® - - I - - I Dorosomo petenense Threadfin Shad Intermediate Omnivore - I - - I Cyprinidae Carps andMinnows IF I Clinostomusfunduloides Rosyside Dace Intermediate Insectivore - 1 - Cyprinelloonolostono Sathrfin Shiner Tolerant Insectivore - 27 1 - 3 C. niveo Whitefin Shiner Intermediate Insectivore 4 ® 29 I I 12 - C. pyrrhomelos Fieryblack Shiner Intolerant N Insectivore - - Noco_s leptocepholus Bluehead Chub Intemmediate Omnivore 2 - 29 2 Notropisomoenus Comely Shiner Intermediate Insectivore - - 1 3 - Notropis hudsonius Spottail Shiner w- Intermediate Omnivore Ir - 8 200 3 N. scepticus Sandbar Shiner Intemmediate Insectivore' - 42 I - - I Semotilusatrormculatus Creek Chub Tolerant Insectivore NIS,- - — I 1 - Ictaluridae N. American Catfishes 1 I Ameiurus bmnneus SnailBullhead Intermediate Insectivorekka, 88 127 12 13 A. cotus White Catfish Tolerant Onmivore 1 - I - 1 A.plotycepholus Flat Bullhead Tolerant Insectivore 13 45 10 37 ktolumspunctotus Channel Catfish 4 Intermediate Omnivore 4 2 3 - Noturusinsignis Margined Madtom Intermediate Insectivore 3 5 1 86 22 Pylodictis oli Flathead Catfish Intemmediate Piscivore - - - 1 Pmecilii " Limabearers 46- - 1 - - GambmiWrooki Eastem Mosquitofish Tolerant sectivore 4 - I 1 2 9 Nbronidae Temperate Basses j Morose omeri White Perch A ® diate Pis civore 2- Centrarchidae Sunfishes I — I Lepomisgibbosus Punpkinseeda Intermediate Insectivore 1 - - - L.gulosus 'Wammouth Sees Intemmediate Insectivore 1- I L. ouritus Redbreast Sunfish Tolerant Insectivore 4 21 1 72 27 L. cyonellus Green Sunfish Tolerant Insectivore - - I 1 6 5— L. mocrochims Bluegill Intermediate Insectivore - - 38 22 Micropterussolmoides Largemouth Bass Intermediate Piscivore 9 7 1 7 1— Percidae Perches I Etheostomoflobellore Fantail Darter Intermediate Insectivore - - 3 - Etheostomoolmstedi Tess ellated Darter Intemmediate Insectivore 2 7 I 113 79 Percoflovescens Yellow Perch Intermediate Piscivore 3 2 I 1 - - Percinocrosso Piedmont Darter Intolerant Insectivore 4 19 I 26 9 Total 347 1 6 4-3 Results Table 4-3 Catch rates (fish/hour) for electrofishing samples (pram and backpack) collected from Pee Dee River at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July Number (fish/hour) 2016. 4-4 U1 TZ2 Taxa 2008 2016 2008 2016 l.ongnose Car - - 1 0.3 - American Eel 4.2 0.4 1.1 ShortheadRedhorse - 0.4 1 - Smallmouth Buffalo 0.8 1 I Threadfin Shad 0.8 1 Rosyside Dace I 61 0.3 Comely Shiner6 - Satinfin Shiner - 9.4Nk 1.2 Whitefin Shiner 1.2 11.8 I 1.2 - Bluehead Chub 0.6 8.3 Creek Chub 0.3 Creek(7hubsucker - 1 0.3 I "Brassy"Jumproc 0.3 1 Fieryblack Shiner1 0.8 Spottail Shiner t 1.2 7.1 1.2 Sandbar Shiner 5 1 Channel Catfish 217" 0.9 - Flathead Catfish- - I - 0.4 Snail Bullhead 6.1 51.8 j 3.4 5.2 White Catfish - - 0.4 Flat Bullhead % .9 18.4 I 2.9 14.8 Channel Catfish - 0.81 I - - Margined Madtom 0.9 2.0 24.6 8.8 EasternMosquitofish 0.3 - I 0.3 3.6 White Perch 0.6 I 1 Pumpkinseed 0.3 1 I Rejlbreast Sunfish 1.2 8.6 I 20.6 10.8 Caeen Sunfish - - I 1 1.7 2.0 Warmouth 0.3 1 I Bluegill - - i 10.9 8.8 Largemouth Bass 2.7 2.0 1 2.0 0.4 Fantail Darter - - 0.9 - Tessellated Darter 0.6 2.9 I 32.3 31.6 Yellow Perch 0.9 0.4 I 1 - - Piedmont Darter 1.2 7.8 j 7.4 3.6 4-4 Results Table 4-4 Biomass collection rates (grams/hour) for electrofishing samples (pram and backpack) collected from Pee Dee River at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016. "Brassy"Jump rockIS5. Weight (grams/hour) j TZl TZ2 Taxa 2008 2016 2008 2016 Longnose Car - - 1 2.3 - American Eel 115.4 4.1 6 ShortheadRedhorse - 326.5 1 Smallmouth Buffalo 1804. I 1 11.4 Threadfin Shad 1 IL Rosyside Dace 127.4 201.2 I 0.3 - Comely Shiner 6.4 2.0 Satinfin Shiner ® 24.9 - 3. Whitefin Shiner 3.9 4.5 ' I 12.0 Bluehead Chub 1.2 1 39.4 0.8 Creek Chub - 0.6 - Creek Chubs ucke Tessellated Darter 0.3 - "Brassy"Jump rockIS5. 16.9 j Fieryblack Shiner 1 7.6 Spottail Shiner 2 Sandbar Shiner 9 1 Channel Catfis 20. 1 804.0 13.7 Flathead Catfis 0.0 I - 58.8 I 1 11.4 31.6 Warmouth 18.4 .2 127.4 201.2 �nailBullhead hite Catfish 0 6.4 t Bullhead 127.9 311.8 I 36.0 230.8 Channel Catfish 891.8 1 - - I Margined Madtom N 8.3 15.1 184.9 58.0 EasternMosquitofish 1.2 - I 0.3 0.8 White Perch 16.9 I 1 Pumpkinseed 6.2 1 I Redbreast Sunfish 74.8 339.2 1 804.0 173.6 Gwen Sunfish - I 1 11.4 31.6 Warmouth 18.4 1 - I - Bluegill - i 327.4 180.0 Largemouth Bass 12.2 11.0 1 45.1 1.6 Fantail Darter - - 3.4 - Tessellated Darter 1.5 2.9 I 69.4 44.8 Yellow Perch 45.4 15.5 I 1 - - Piedmont Darter 6.2 51.4 j 30.3 17.2 4-5 Results Table 4-5 Catch rates (fish/haul) for seine hauls collected from Pee Dee River at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016. Table 4-6 Biomass collection rates (grams/haul) for seine hauls collected from Pee Dee River at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016. Number Number (fish/haul) U1 (fish/haul) TZ2 Taxa 2008 2016 2008 2016 Largemouth Bass - 0.2 1 - Yellow Perch - 0.1 1 I Eastern Mosquitolis h 0.3 - I 0.7 Tessellated Darter - ® - 0.1 Satinlin Shiner 0.3 0.1 Spottail Shiner A&0.4 I 0.3 Comely Shiner 'Ap- O -1 'M6,- Sandbar Shiner fx 2.6 I - Table 4-6 Biomass collection rates (grams/haul) for seine hauls collected from Pee Dee River at Sites TZ1 and TZ2 below Tillery Dam during August 2008 and July 2016. 4-6 Mass Mass (grams/haul) TZ1 (grams/haul) TZ2 Taxa 2008 2016 2008 2016 Largemouth Bass 0.8 1 Yellow Perch .6 1 I EasternMosquitotilk 0.3 sho 1 0.1 0.1 Tessellated Darterq%- - j - 0.1 Satintin Shiner 2.3 0.2 Spottail Shin 0.7 1 - 0.3 melt' Shine 10.1 ar Sln 19.8 ! - - 4-6 Results Table 4-7 Characteristics of the fish community in Pee Dee River below the Tillery Dam at Sites TZ1 and TZ2 during 2008 and 2016. TZl I TZ2 Metric 2008 2016 1 2008 2016 No. 1 Number of taxa or species richness 18 17 1 21 16 No. 2 Number of individuals 160 347 I 630 237 No. 3 Number of darter species 2 2 j 3 2 No. 4 Number oftninnow species 2 4 6 4 No. 5 Number ofNorth American catfish I 5 4 4 5 species No. 6 Number of sucker species 0 2 j 1 0 No. 7 Number of sunfish species 2 4 4 No. 8 Number of intolerant species 1 1 2 No. 9 Percent tolerant individuals 14% 27% I 15% 35% No. 10 Percent omnivore and herbivores ® %/o 4% j 37% 3% No. 11 Percent piscivores 1W 3% 2%/o n. V&< I% No. 12 Percent insectivores 78 th 93% 61% 97% No. 13 Percent Green Sunfish 0 0 I 1% 2% No. 14 Percentage of specieswith ip e I o 56 /0 o 59 /o o I 67 /% 0 50 /% age groups I No. 15 Number of nonnative species and percentage of nonnative individuals to 1(3%) 4(2%) I 3(2%) 2(3%) native individuals I I No. 16 Percentage of fish with disease, fin _ erosion, lesions, or tumors 0 o I <1 /0 0 The most abundant fish species within the aquatic community at Site TZl in 2016 were Satinfin Shiner, Whitefin Shiner, Sandbar Shiner, Snail Bullhead, Flat Bullhead, Redbreast Sunfish and Piedmont Darter representing 89% of the total catch. The most abundant fish species collected in both 2008 and 2016 was Snail Bullhead. Percent of tolerant species increased from 2008 and compromised �-7%/0 of the total 2016 fish community collected at_Site_- - - Deleted: TZl (Table 4-5). Fish species collected in low numbers at Site TZ1 in 2016 were Tessellated Darter, Spottail Shiner, American Eel, Shorthead Redhorse, Smallmouth Buffalo, Threadfin Shad, Channel Catfish, Margined Madtom, Largemouth Bass and Yellow Perch, representing I% of the total catch. Piedmont Darter was the only intolerant species collected at Site TZ1 - - Deleted: both sample years, but was a numerically dominant species in 2016 (i.e., >5%/o total catch). North Deleted: s American catfishes, mainly Snail Bullhead, and Flat Bullhead were prevalent at Site TZ1 both - � Deleted: s 4-7 Results sample years. Insectivorous fish continued to dominate the trophic feeding guilds at Site TZ1 due to the large number of bullheads collected both years as well as minnows collected during 2016. The number of fish species with multiple age groups present was similar to 2008 with 59% of species having multiple age groups (Table 4-8). Of the 17 species collected at Site TZ1 in 2016, four are considered non-native (i.e., Channel Catfish, Smallmouth Buffalo, Threadfin Shad and Yellow Perch) by the NCDEQ (NCDEQ 2017). Channel Catfish and Yellow Perch were the only non-native species collected during the 2008 s e (Table 4-2). None of the fish collected to date in TZ 1 have showed signs of disease, fin , lesions or tumors------------ Formatted: Font color: Auto The most abundant fish species pt Site TZ2 i were Margined Madtom, _Flat__ , - Deleted: within the aquatic eoru„un ty Bullhead, Snail Bullhead, Redbreast Sunfish, Bluegill and Tessellated Darter. The single most abundant fish species collected in 2016 was Tessellated Darter (n = 79) compared to Spottail Shiner (n = 200) in 2008 which made up a 0% of e collected individuals. Tolerant species (i.e., Satinfin Shiner, Whit Catfish, Flat astern Mosq tsh, Redbreast Sunfish and Green Sunfish) comprised 35%.of the fis unity at Site TZ2 in 2016, which more than doubled the 14% of tolerant species collected in 2008 (Table 4-5). Eleven species in 2008 and 10 species in 2016 consisted of less than 10 individuals (Table 4-2). A small number of Piedmont Darters, an intolerant species, were collected at Site TZ2 both sample years. Insectivorous fish dominated the trophic feeding guilds at Site TZ2 both sample years which was comprised mainly f North American catfishes, sunfishes and perches. The number of fish species potentially having multiple age groups dec4ased from 67% in 2008 to X50% in 2016_ - - Formatted: Font color: Auto (Table 4-8). In 2008 at Site TZ2 three non-native species fi.e., Green Sunfish, Channel Catfish_ - - Formatted: Fantcolor:Auto and Comely Shiner) were collected (NCDEQ 2017). In 2016 at Site TZ2 two non-native species (i.e., Flathead Catfish and Green Sunfish) were collected. None of the fish collected within Site TZ2 showed signs of disease, fin erosion, lesions or tumors in 2016, and in 2008 one Piedmont Darter was collected with a misting left pelvic fin (Duke Energy 2014)-------------------- Formatted: Font color: Auto 4-8 Results Table 4-8 Individual lengths (1 specimen collected), mean lengths (total length, mm) and size ranges (minimum and maximum) of fish collected from Pee Dee River below Tillery Dam during 2008 and 2016. TZl TZ2 Taxa 2008 2016 2008 2016 L.ongnose Car - - I 152 - Rosyside Dace 47 Comely Shiner 66(37-86) Creek Chub I 52 CreekChubsucker - 46 `Brassy"Jumprock 120 1 I White Perch 137 (130-143) 1 - American Fel 243(141-298) 235(200-300) Shorthead Redhorse 800 1 I Smallmouth Buffalo 2211(1948-2473)1 Threadfin Shad 66 (65-67) Satinfin Shiner Aff- 71(60-112)0 - 69(57-79) Whitefin Shiner 70(65-72) 71(57-97) 1 73(60-94) - Bluehead Chub 53(42-64) 65(46-138) 42(39-45) Fieryblack Sh 89(82-93) Spottail ShineAc- Flathead 71(59-95) 1 107 (93-117) 54(53-55) Sandbar Shinr 94(84-108) 1 I Catfish N - - _ - 245 Snail Bullhead 120(3L j448) 123 (52-204) 1137 (43-209) 130 (36-215) White Catfish 74%, 113 Flat Bullhead 121(145-171 620) 74(43-197) 86(30-195) Channel Catfish 129 (121-138) 109 044-1141)1135 (121-146) - @Aargined Madtom 97(93-100) 90(79-98) 84(32-131) 85(43-104) 'Eastern Mosquitofish 35(20-56) 32(21-42) 23(16-53) Redbreast Sunfish %29 (93-203) 117 (62-181) 1117 (48-206) 89(55-140) Gwen Sunfish - 61(34-112) 91(83-107) Pumpkins 102 1 I Warmouth 135 I Bluegill - 107 (20-159) 97(62-131) Largemouth Bass 61(34-85) 70(45-92) 117 (47-233) 67 Fantail Darter I 70(68-71) - Tessellated Darter 65(60-69) 43(36-55) 61(34-76) 51(33-77) Yellow Perch 162 (135-187) 154 (143-165) 1 I Piedmont Darter 79(71-85) 85(73-93) 1 70(47-86) 74(49-93) 4-9 Results 4.3 Environmental Results Continuous DO values were collected every 15 minutes near Site TZ1 by the USGS Gaging Station No. 0212378405 at HWY 731 Bridge (Figure 4-2) and by the HOBO data logger at Site TZ2 from May 1 through November 30, 2016 (Figure 4-3). The DO measured below the state instantaneous minimum standard of 4.0 mg/L for thirty minutes (i.e., 2300-2330 hours) on August 6, 20163 near Site TZ1 (i.e., Tillery Development downstream compliance point). Instantaneous DO values were documented at 3.9, 3.6 and 3.4 mg/L before increasing above the 4.0 mg/L standard at 2345 hours. These three variances below the minimum standard near Site TZl and 96 variances at Site TZ2 during 2016 are markedly fewer than the 2008 monitoring season with 5168 and 2779 variances, respectively (Table 4-9). The daily average DO remained above the state standard of 5.0 mg/L during 2016 at both sites, which was an improvement from the 2008 sample season when the daily average DO registered below 5._ at Site TZ1_and_ , - Deleted: where TZ2 80 and 11 instances, respective) (Table 4-9). River flows documented ite TZI at the USGS Gaging Station 0212378405 at HWY 731 Bridge remained above the minimum continuous flow of 330 cfs as required by the New License jTable 4-9, Appendix A; FERC , - Deleted: 2015). In-situ water quality analyses we erfo _ in -e 008 -and 2016 fisheries and_, , - Deleted: i benthic sampling event (Table 4-10). TZl 14 0 May June July August September October November 2016 Figure 4-2 Instantaneous dissolved oxygen data collected every 15 minutes from May 1 through November 30, 2016 near TZ1. 'FERC Docket No. P-2206-068, January 11, 2016 4-10 Results TZ2 May June July August September October November 2016 Figure 4-3 Dissolved oxygen levels col lec ery 15 \(NA:Ap ay 1 through November 30, 2016 at TZ2. Table 4-9 Variances from NC Water Quality Standards en for the 2016 monitoring period May 1—November 30cable). Environmental Parameters TZl TZ2 2008 2016 2008 2016 Dissolved Oxygen—daily 80 0 1 11 0 average Dissolved Oxygen— ® 1 5168 3 12779 96 instantaneous minimum I Flow— daily minimum 0 INA NA 4-11 Results Table 4-10 Temperature, dissolved oxygen, �pecific conductance,pH and turbidity_ , - Commented [Cc6]: In the table below, spell out the values collected during the macroinverteb rate and fish community headings. assessments below the Tillery Development during 2016. `Turbidity was not recorded on these 5.0 Discussion The shallow water aquatic community in the Development was surve for macroinvertebrates and fish Survey results collected during 2016 document the first_sam community after implementation of the terms and conditions of sm Dee River_ below _the _Tillery_ - - Deleted: mainstem g summer 2008 and 2016. y ar of monitoring the aquatic_ - - f Deleted: s New License. 5.1 Benth' Macroinvertebrate The benthic community has shown v ent based upon the NCDEQ Benthic SOP criteria since implementation of the minimum ow regime and DO enhancements required by the New License. This is most eviden e upstream Site TZl. Total taxa richness increased from 46 in 2008 tow, 6 in 2016, a 60 percent increase, and EPT richness has doubled from 11 in 2008 to 22 in 2016, a 100 percent increase (Table 4-1). The bioclassification improved from Fair in 2008 to Good -Fair in 2016. Site TZ2 showed improvement as well. While the bioclassification was unchanged from Good -Fair, the EPT richness changed from 14 to 22, a 64 percent increase (Table 4-1). 5.2 Fish Community Deleted: stream characteristics of the Pee Dee River currently As discussed in Section 3.0 above and in the Study Plan for Aquatic Life Monitoring, the_, - restricts the ability of Deleted: to rate the overall health of the river NCIBI scoring system is not applicable for rating large, unwadable rivers based on electrofishing- - Deleted:, and seine samples however, NCIBI metrics can help track the stealth of the Pee Dee River over, ' Deleted: within the NCIBI Deleted: overall 4-12 Temp DO sp. Cond Turb Site Sample Date (°C) (mg/L) (1tS/cm) pH (NTU) TZl Benthic 7/26/2008 23.5 7.6 111 7.4 1.0 TZ2 Benthic 7/27/2008 24.6 6.6 111 7.2 1.0 TZl Fish 8/2/2008 25.1 5.3 115 7.1 TZ2 Fish 8/1/2008 25.2 6.4 109 7.1 TZl Benthic 7/6/2016 25.3 7.,d 88 7.2 1.6 TZ2 Benthic 7/7/2016 25.3 90 7.2 2.0 TZl Fish 7/13/2016 28.0 ® 85 7.7 1.5 TZ2 Fish 7/12/2016 25.2W 6.2 T 91 7.0 4.4 `Turbidity was not recorded on these 5.0 Discussion The shallow water aquatic community in the Development was surve for macroinvertebrates and fish Survey results collected during 2016 document the first_sam community after implementation of the terms and conditions of sm Dee River_ below _the _Tillery_ - - Deleted: mainstem g summer 2008 and 2016. y ar of monitoring the aquatic_ - - f Deleted: s New License. 5.1 Benth' Macroinvertebrate The benthic community has shown v ent based upon the NCDEQ Benthic SOP criteria since implementation of the minimum ow regime and DO enhancements required by the New License. This is most eviden e upstream Site TZl. Total taxa richness increased from 46 in 2008 tow, 6 in 2016, a 60 percent increase, and EPT richness has doubled from 11 in 2008 to 22 in 2016, a 100 percent increase (Table 4-1). The bioclassification improved from Fair in 2008 to Good -Fair in 2016. Site TZ2 showed improvement as well. While the bioclassification was unchanged from Good -Fair, the EPT richness changed from 14 to 22, a 64 percent increase (Table 4-1). 5.2 Fish Community Deleted: stream characteristics of the Pee Dee River currently As discussed in Section 3.0 above and in the Study Plan for Aquatic Life Monitoring, the_, - restricts the ability of Deleted: to rate the overall health of the river NCIBI scoring system is not applicable for rating large, unwadable rivers based on electrofishing- - Deleted:, and seine samples however, NCIBI metrics can help track the stealth of the Pee Dee River over, ' Deleted: within the NCIBI Deleted: overall 4-12 References time. Duke Energy and the ALMT agreed to evaluate the fish criteria (and determine success) in a qualitative manner. A qualitative assessment will provide trending information on the fish communities. Two qualitative observations are noted kirst ' 2016, the total number of fish collected - -I Deleted: The following at Site TZ1 increased, but decreased at Site TZ2, and both sample locations collected fewer ` � � Deleted.. j Deleted: 1. number of taxa. Factors that may have influenced the 2016 data include the increased stream Deleted: 1 flows over that in 2008 and the presence of Hydrilla downstr�>lrn of the Tillery Development. Both increased flows and Hydrilla limit sampling e ,, tc and efficacy, which could_ - - Deleted: a sampler's abifity to collectfish potentially ias the number of individuals and taxa co_ ; nflue_nce metric scores. - - Deleted: affect < econd, Iwo intolerant fish species were co ted in 20 'thin the sample_sites, with Deleted: thus potentially creating a sampling bias ---------------- - - ---- ---- ------ - ---- -- Deleted:2. Piedmont Darter being a numerically abundant fish species at Site " The incidence rate_of— Deleted: During 2016, fish with signs of disease, fin erosion, lesions or tumors onsisted ly one individual Deleted: collected occurrence in 2008. hi both years, t re was a low number of Green Sunfish ent. Increased numbers of intolerant species, little to no tsh with signs of disease, fm erosion, lesions or tumors, and low number of Green Sunfish are considered positive results. 5.3 Environment*w N 41&, '% Baseline water quality results collected during 2008 indicated that DO conditions were often below the state standards during generation and non -generation periods within Sites TZ1 and TZ2.` In 2016 ater X2022 er. impro ed conditions over those observed in 2008 - - Formatted: Font color: Auto at both sit Deleted: suggests - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Dee TZ1 and TZ2 The fish and aqubrate communities will be surveyed on three-year intervals for three more cand 2025). Data collected during subsequent years will be compared to previous data collections (e.g., 2008 and 2016) to further assess the benthic macroinvertebrate and fish communities in the Pee Dee River below Tillery Hydroelectric Plant. ------------------------------------------------------------- -5-Z--------------------------- Deleted----------------Section Break (Continuous)---------------. References 6.0 References Bain, M. B., and V. H. Travnichek. 1996. Assessing impacts and predicting restoration benefits of flow alterations in rivers developed for hydroelectric power production. Pages B543 - B552 in M. Leclerc, H. Capra, S. Valentin, A. Boudreault, and Y. C1tq (editors). Proceedings of the second IAHR Symposium on Habitat Hydraulics, Ecohydraulics 2000. Duke Energy. 2014. Yadkin -Pee Dee River Hydroelectric Project FERC No. 2206. Aquatic Life Monitoring Below Tillery Development. 26 pp. 2015. Study Plan for Aquatic Life Monitoring in th Dee River Reach below the Tillery Hydroelectric Plant. Yadkin -Pee Dee River ydroelectric Project FERC No. 2206. Final REV 2 (December 2015). Federal Energy Regulatory Commission (FERC Order Iss ew Licenses, Project No. 2206-030. Issued April 1, 2015. 174 2016. Order Approving Aquatic Life Mon' oring Plan Pursuant to Article 401 (A), Project No. 2206-056. Issued January 6, 2016. Gray, J. S. 1989. Effects of environmental stress on sp of rich assemblages. Biological Journal of the Linnean Society. 37: 19-3 Karr, J. R. 1981. Assessment of biotic integrity using fish comm s. Fisheries. 6:21-27. 1991. Biological integrity: A long -neglected aspeck water resources management. Ecological Applications 1:66-84. Karr, JR_, K.D. Fausch, P L. Angermeier . R. Yant, I. J. Schlosser. 1986. Assessing biological integrity in running waters a metho and its rationale. Illinois Natural History Survey Special Publication 5, September 1986, Champaign, IL. 33 pp. North Carolinaikepartment of Environmental Quality. 2016. Standard Operating Procedures for the Collection and Analysis of Benthic Macroinvertebrates. February 2016 (Version 5.0). Division of W ter Reso s; Water sciences Section; Biological Assessment Unit April 4, 2016. North Carolina Department of Environmental Quality. 2017. Native and Nonindigenous Freshwater Fish in North Carolina. https:Hdeq.nc.gov/about/divisions/water- resources/water-re source s-data/water-sciences-home-naae/b io loa ical-as ses sment- branch/native-nonindigenous-fish. Accessed January 5, 2017 North Carolina Division of Water Resources 2006. Standard operating procedures for benthic macroinvertebrates. Biological Assessment Unit. July 2006. North Carolina Department of Environmental and Natural Resources, Division of Water Quality, Environmental Sciences Section. July 26, 2006. 6-1 References North Carolina Division of Water Resources. 2013. Standard Operating Procedure Biological Monitoring. Stream fish community assessment program. Biological Assessment Unit. December 2013. North Carolina Department of Environmental and Natural Resources, Division of Water Resources, Environmental Sciences Section. December 01, 2013. 52 PP - 2008. Yadkin -Pee Dee Project for Tillery and Blewett Falls Reservoirs. Rockingham, Stanly, Anson, Richmond and Montgomery Counties. DWQ 02010437, Version 02. Federal Energy Regulatory Commission Project Number 2206. Water Quality Certification Mod 1. North Carolina 401 Water Quality Certification. September 30, 2008. Progress Energy 2006a. Yadkin -Pee Dee Hydroele Pro t No. 2206. Pee Dee River instream flow study. Final report. Water Resources Working Group. Issue No. 5—Evaluate relationships between project operations/hydraulics and aquatic habitat, water quality, and fish migrations. April 2006. 2006b. Yadkin -Pee Dee Hydroelectric Project No. 2206. Shallow w fish, crayfish, and mussel surveys of the Pee Dee River and tributaries. Water Resources Group Issue No. 1— Describe Current Resident ktv r Aquatic sources Of Project Area. April 2006. . 2010. Yadkin -Pee ee ier Hydroe ectric rolec l%C No. 2206. Continuous water quality monitoring in the Pee Dee River below the Tillery and Blewett Falls Plants, May -October 2006-200 . 6-2 Appendices APPENDIX A DAILY AVERAGE DISSOLVE" OXYGEN, MINIMUM INSTANTANEO ISSOLVED OXYGEN AND DAILY MINI FLOW COLLECTED NEAR TZ1 (USGS GAGING STATION NO. 0212378405 AT HWY 731 BRIDGE) AND AT TZ2 FROM MAY 1 —NOV R 30, 2008 AND 2016 NO. 0212378405) AND AT TZ2 FROM 1 —NOVEMBER 30, 2008 AND 2016 O Appendix A - 1 Date 1 -May 2 -May 3 -May 4 -May 5 -May 6 -May 7 -May 8 -May 9 -May 10 -May 11 -May 12 -May 13 -May 14 -May 15 -May 16 -May 17 -May 18 -May 19 -May 20 -May 21 -May 22 -May 23 -May 24 -May 25 -May 26 -May 28 -May 29 -May 30 -May Dissolved Oxygen Daily Aveimge TZl 2008 TZ2 2008 2016 2008 2016 N_ D 7_.75 ND 7.76 ND 8.32 11.41 8.27 NTJ 7.86 10.33 7.81 ND 8.74 8.9 8.24 ND 9.47 9.01 9 ND 8.89 9.04 8.83 ND 8.98 7.32 9.02 ND 8.8 7.77 8.99 ND 8.59 8.24 8.69 ND 8.66 9.72 9.05 ND 8.8 8.86 6.2 ND 8.22 10.7 _9.17 8.44 ND 7.97 9.51 8.24 ND 8.28 7.4 8.33 ND 8.11 8.01 8.11 ND 7.55 10.13 8.1 ND 6.98 9.03 7.12 ND 7.52 7.73 7.77 ND 6.85 6.47 6.65 D 6.71 2AINEENEEM 6.72 ND 6.88 5.5 6.98 ND 7.4 7.5Nk 7.33 ND 8.05 8.38 8.05 ND 7.48 8.42 2 ND 7.91 8.75 .26 ND _ 7.96 7.86 ND 7.04 6.6 7.52 ND 7.69 9.39 8.45 Na, 6.97 8.2 7.01 ND 6.76 7.41 7.02 ND , 7 6.54 6.63 Dissolved Oxygen Daily Minimum TZl TZ2 2008 2016 2008 2016 ND 7.1 ND 6.32 ND 6.6 7.13 6.32 ND 7 6 6.24 ND 7.9 5.85 7.78 ND 8.8 6 8.46 ND 6.8 5.9 6.62 ND 6.8 7.21 ND 6.8 .06 6.79 ND 5.33 6.31 ND 3 6.53 ND " 6.7 6.43 ND 6.2 5.A%h, 6.04 ND 6 5.72 q%66 ND 6.1 4.84 N 5.7 .36 5.Iq ND 5.03 6.04 ND 5.25 5.07_ ND 5. 4.99 5.32 ND 5.9 4.67 5.08 ND Ift,8 4.78 5.34 ND 5.8 4.74 5.87 ND 5.5 _4.74 5.55 ND 7 4.44 7.38 ND 6 4.87 5.76 ND 6 4.6 6.15 ND 6 4.01 5.98 ND 6 4.38 5.75 ND 5.3 4.89 6.02 ND 5.2 4.38 4.03 ND 5 4.19 4.17 ND 5.3 4.55 4.5 Appendix A - 2 Appendices Minimum Flow TZl 2008 2016 ND 401 ND 393 ND 426 ND 19500 ND 418 ND 435 ND 480 ND 462 ND 480 ND 471 ND 453 ND 426 ND 489 ND 489 ND 418 D 480 ND 435 ND 435 ND 471 ND 480 ND 453 ND 489 ND 462 ND 480 ND 444 ND 462 ND 453 ND 462 ND 426 ND 435 ND 453 Appendices Appendix A - 3 Dissolved Oxygen Daily Average Dissolved Oxygen Daily Minimum Minimum Flow Date TZl TZ2T71 TZZ 2008 2016 2008 2016 2008 2016 2008 2016 2008TZl 2016 1 -Jun ND 6.7 7.71 6.72 ND 5.3 4.1 4.3 ND 453 2 -Jun ND 6.44 7.98 6.74 ND 5.2 4.32 4.8 ND 462 3 -Jun ND 6.71 7.38 6.79 ND 5.4 4.45 4.87 ND 489 4 -Jun ND 7.47 7.45 8.23 ND 5.4 4.14 5.14 ND 519 5 -Jun ND 7.17.93 6.99 ND 5.6 4.3 4.69 ND 444 6 -Jun ND 6.7 7.77 7.13 ND 5.2 3.7 5.13 ND 462 7 -Jun ND 7.1 8.6 7.24 ND 5.7 88 4.93 ND 480 8 -Jun ND 6.17 7.24 6.54 ND 5.2 9 4.91 ND 528 9 -Jun ND 6.2 6.72 6.48 ND "4.19 4.65 ND 591 10 -Jun ND 6.32 6.62 6.65 ND 34 5.54 ND 509 II -Jun ND 6.38 6.49 6.25 ND 5.5 4A& 4.4 ND 480 12 -Jun 4.3 6.53 7.64 6.49 3.21 5.3 4. ® 4.66 ND 444 13 -Jun 5.52 6.44 6.3 6.4 2.49 5.1 4.04 91 ND 462 14 -Jun 4.58 6.47 6.53 6.5 y34 5.4 4.27 ND 471 15 -Jun 4.89 6.77 6.43 6.87 2.4 5 4.11 4. ND 435 16 -Jun 4.64 6.39 6.49 6.5 2.31 4.06 4.63 D 462 17 -Jun 4.67 6.37 6.2 6.34 2.47 3.99 3.83 ND 435 18 -Jun 4.55 6.29_: 6.37 6.14 68 4. 3.98 3.34 ND 480 19 -Jun 4.85 6.29 6.5 5.64 5.1 88 2.72 ND 509 20 -Jun 4.8 6.27 7 6.4 2.7 1 4.46 ND 489 21 -Jun 4.92 6.8 7.08 2.64 3. 4.32 ND 444 22 -Jun 4.67 6.37 5. 6.31 2.5 5.3 .14 4.36 ND 462 23 -Jun 4.18 6.52 6.35 Ilk 6.51 2.65 5.3 3.36 4.26 ND 435 24 -Jun 4.41 6.38 6.34 44 2.33 5.3 3.36 4.19 ND 453 25 -Jun 4.31 6.36 4.91 , 2.31 . 5.2 3.48 4.26 ND 435 26 -Jun 3.51 6.21 . 6.69 6.23"". 2.09 5 45 3.96 ND 471 27 -Jun 4.35 6.11j.6.01 5.97 2.31 4.9 3.48 4 ND 462 28 -Jun 3.64 6.31 ® 6.01 6.06 2.12 5.2 3.22 4.27 ND 401 29 -Jun 4 6.36 6.76 6 2.14 5.1 3.79 4.04 ND 453 30 -Jun 4.45=k,6.24 6.7 5.7 2.74 5.3 3.92 4.03 ND 471 Appendix A - 3 Date 1 -Jul 2 -Jul 3 -Jul 4 -Jul SJul 6 -Jul 7 -Jul 8Jul 9Jul lOJul 11Jul 12 -Jul 13 -Jul 14 -Jul 15Ju1 16 -Jul 17 -Jul 18Ju1 19Ju1 20Jul 21 -Jul 22 -Jul 23 -Jul 24 -Jul 25 -Jul 26 -Jul 27 -Jul 28 -Jul 29 -Jul 30Jul 31 -Jul Dissolved Oxygen Daily Average TZl 2008 TZ2 2008 2016 2008 2016 4.87 6.17 6.17 5.85 3.86 6.21 5.9 6.07 3.92 6.03 5.99 5.85 3.8 5.93 6.43 5.59 4.32 5.46 6.05 5.29 4 6.1 6.4 6.18 4.18 5.97 6.29 6.11 4.32 6.04 5.66 5.98 4.39 5.84 6.44 5.84 4.91 5.59 5.31 5.6 3.97 5.68 6.39 5.84 4.63 6.13 6.34 6.28 4.55 6.13 5.93 6.45 4.38 5.76 5.8 5.87 4.55 5.87 5.55 5.74 4.11 6.32 5.89 5.95 4.61 6.1 6.68 5.59 4.87 5.8 7.05 5.57 5.18 6. 2.54 6.26 4.53 4.6 6. ® 6.35 4.34 1.67 6.3Ilk 5.97 3.77 6.3 5.93 JE 6.07 3.69101b&. 12 6.13 6.19 3.88 5.4, 5.57 5.75 3.6 5. 5.55 5.88 3.67 6.48 7.49 6.45 4.62 6.09 5.81 6.34 3.3 6.04 5.65 6.08 3.5 ®® 27 5.72 6.24 3.24 6.1 6.04 6.02 3.57 6.21 7.55 6.35 Dissolved Oxygen Daily Minimum TZl TZZ 2008 2016 2008 2016 2.92 4.8 3.54 4.03 2.43 5.1 3.26 4.02 2.34 4.7 2.41 3.91 1.56 4.9 3.16 3.74 2.26 4.6 3.45 3.86 2.52 4.7 2.�1 4.22 4.7 3.03 4.51 _1.92 2.15 4.9 2.72 4.62 2.45 5 4.59 2.52 4.6 3. 4.37 2.61 4.8 3.66® 4.51 2.36 4.4 2.63 4.4 2.18 5 L3.2 4.79 2.79 5 3.15 4.45 a 2.43 1W.. 2.98 4.57_ 64 5'.I%k 3.02 4.69 2.64 4.9 .45 4.25 2.6 J .4 4.35 2.56 1 2. 4.67 2.62 5 .91 4.62 2.45 5.2 2.54 4.56 1.71 4.6 2.44 4.63 1.67 4.9 2.81 4.89 2.1 f 5.2 2.5 4.69 1.68 4.8 2.21 4.61 1.22 5.2 3.45 4.71 2.1 5.2 3.02 5.08 1.51 5.2 2.42 4.93 1.66 5 2.9 4.42 1.61 5.1 2.88 4.46 1.68 5.3 3.82 4.94 Appendix A - 4 Appendices Minimum Flow TZ1 2008 2016 ND 453 ND 453 ND 418 ND 453 ND 444 ND 569 ND 426 ND 602 ND 462 ND 426 ND 462 ND 718 ND 453 453 ND 462 ND 435 ND 471 ND 480 ND 471 ND 453 ND 453 ND 435 ND 462 ND 462 ND 435 ND 453 ND 471 ND 435 ND 418 ND 426 ND 471 Appendices Appendix A - 5 Dissolved Oxygen Daily Average Dissolved Oxygen Daily Minimum Minimum Flow Date T71 T72 TZl T72 TZl 2008 2016 2008 2016 2008 2016 2008 2016 2008 2016 1 -Aug 4.61 6.18 7.5 6.35 2.11 5.2 4.1 5.13 ND 444 2 -Aug 4.48 5.99 7.4 6.2 1.87 5.1 4 5.13 ND 489 3 -Aug 3.7 6.28 5.97 6.39 2.04 5.5 2.59 5.28 ND 480 4 -Aug 3.24 5.56 5.54 5.68 1.29 5.1 2.52 5.1 ND 480 5 -Aug 2.96 5.99 6.03 5.92 1.26 5.3 3.07 5.42 ND 10200 6 -Aug 3.53 5.74 6.04 5.73 1.23 3.4 3.13 4.82 ND 694 7 -Aug 3.11 5.94 6.43 5.78 1.4 4.5 4.45 ND 471 8 -Aug 3.42 6.08 6.98 6.02 1.41 5.3 .11 4.61 ND 471 9 -Aug 4.18 6.12 6.35 6.06 1.64 5. 3.32 5.32 ND 462 10 -Aug 3.74 5.77 6.36 5.91 1.9 4. V W.39 5.15 ND 462 11 -Aug 3.9 6.18 6.69 6.18 1.97 5.4 5 ND 782 12 -Aug 3.84 5.92 5.03 6.05 1.7 5.5 3.'i%k,5.34 ND 489 13 -Aug 3.41 6.36 ND 6.43 1.65 5.6 ND 54 ND 426 14 -Aug 5.01 6.27 ND 6.44 1.83 5.6 ND 5.49 ND_ 480 15 -Aug 5.18 6.35 ND 6.54 2.23 5.6 ND 5.61 ND_ 480 16 -Aug 6.74 6.35 ND 6.49 4.56 5.5 ND 5.44 D 471 17 -Aug 5.93 6.26 4.94 6.3 4.29 5. 4.92 5.34 ND 435 18 -Aug 5.03 6.44 2.41 6.63 4.48 5. 2.07 5.39 ND 453 19 -Aug 2.22 6.16 2.75 6.32 2.05 5.2 84 5.19 ND 471 20 -Aug 2.89 6.3 .7 6.47 1.94 5.3 5.27 ND 480 21 -Aug 4.04 6. 6.34 2.38 5.3 2. 5.17 ND 435 22 -Aug 3.31 6.3 4.4ML 6.75 1.92 5.3 .5 5.21 ND 409 23 -Aug 3.19 6.3 6.24' 6.66 1.96 5.2 3.09 5.24 ND 489 24 -Aug 4.39 6.06 .26 , 6.61 2.17 5.2 3.22 5.24 ND 471 25 -Aug 3.86 6.28 5.18 6.73 2.38 5.2 3.37 5.3 ND 453 26 -Aug 3.65 6.22 5.35 6.62 2.51 5.2 2.83 5.22 ND 444 27 -Aug 3.76 6.14 4.46 6.56 2.49 5.1 3.41 5.31 ND 489 28 -Aug 4 6.26 7.1 2.67 5.1 4.19 5.35 ND 444 29 -Aug 6.2 6.22 6.67 6. 3.61 5 4.56 5.1 ND 426 30 -Aug 5.1 6.16 6.5 3.21 5 3.81 5.23 ND 489 31 -Aug 5.03 ® 6 5.6 6.38 3.09 5.1 3.89 5.32 ND 480 Appendix A - 5 Appendices Dissolved Oxygen Daily Average Dissolved Oxygen Daily Minimum Minimum Flow Date TZl T72 TZl T7Z TZl 2008 2016 2008 2016 2008 2016 2008 2016 2008 2016 1 -Sep 4.17 6.22 5.51 6.5 3.26 1 5.1 3.4 5.23 ND 453 2 -Sep 4.32 5.83 4.97 5.9 2.94 5.1 4.07 5.11 ND 528 3 -Sep 4.08 6.93_: 4.94 6.97 3.12 5.4 3.69 5.72 ND 453 4 -Sep 4.31 6.81 5.27 6.82 2.86 5.2 3.57 5.3 ND 426 5 -Sep 4.21 6.98 4.96 7.1 2.62 5.3 2.87 5.12 ND 444 6 -Sep 3.94 6.77 5.17 7.33 2.59 5.2 3.14 5.32 ND 426 7 -Sep 3.98 6.6 5.1 7 2.31 &34 5.38 ND 435 8 -Sep 4.47 6.27 5.81 6.75 2.7 5.56 ND 462 9 -Sep 4.8 6.17 5.76 6.63 3.38 5.21 ND 453 10 -Sep 5.25 6.42 6.87 6.8 3.235.27 ND 426 11 -Sep 6.05 6.29 7.07 6.8 3.875.28 ND 444 12 -Sep 6.19 6.42 6.64 6.95_ 3.71 5.75 ND 435 13 -Sep 5.97 6.49 6.9 6.99 3.97 5.1 4.4 77 ND 426 14 -Sep 6.26 6.44 6.57 6.98 4.11 4.8 4.75 ND 418 15 -Sep 5.92 6.53 6.98 6.95 4.16 4.9 4.8 5. ND 444 16 -Sep 6.68 6.56 6.91 6.87 4.89 5. 5.08 5.42 435 17 -Sep 6.93 6.72 6.82 7.0 5.9 5. 5.6 5.63 ND 409 18 -Sep 7.46 6.42 6.35 6.7 6.3 4. 5.28 5.4 ND 418 19 -Sep 6.93 6.09 6.31 6. 6.05 4.8 28 5.32 ND 409 20 -Sep 7.07 5.96 6.96 6.48 5.7 5.6 ND 444 21 -Sep 7.9 6.2 6.18 6.73 6.22 4. 5.6 ND 426 22 -Sep 8.3 6.31® 7.714L6.83 6.27 5 .13 5.75 ND 444 23 -Sep ND 6.18 6.86 .74 STD 4.9 5.63 5.74 ND 435 24 -Sep ND 6.15qj 7.37 1 ND 4.9 5.41 5.67 ND 471 25 -Sep ND 6.64 7.5 ND 5.1 5.29 5.78 ND 480 26 -Sep ND 6.27 6.9 ®6.67 ND 4.7 5.29 4.91 ND 453 27 -Sep ND 6.7 6.18® .82 _ND 5.3 5.19 5.46 ND 519 28 -Sep ND 6.09 5.47 6. _ND 5.1 4.85 5.51 _ND 549 29 -Sep 7.01 5. 6. _ND 5.1 4.62 5.18 _ ND 569 30 -Sea N 6.5 6. 6.65 ND 4.9 4.61 5.51 ND 480 Appendix A - 6 Appendices Appendix A - 7 Dissolved Oxygen Daily Aveimge Dissolved Oxygen Daily Minimum Minimum Flow Date TZl TZ2 TZl TZ2 TZl 2008 2016 2008 2016 2008 2016 2008 2016 2008 2016 1 -Oct 5.88 6.49 7.11 6.81 4.49 4.8 4.81 5.35 ND 489 2 -Oct 6.64 6.65 7.65 6.87 4.32 5.1 5.26 5.29 ND 509 3 -Oct 7.01 6.75 7.85 7.17 4.95 5.3 5.71 5.61 ND 519 4 -Oct 7.5 6.65 7.56 7.11 5.55 5.3 5.85 5.65 ND 499 5 -Oct 6.81 6.91 7.58 7.19 5.37 5.5 5.67 5.83 ND 453 6 -Oct 7.62 7.04 7.18 7.36 5.31 5.6 5.84 6.22 ND 453 7 -Oct 9.19 6.1 6.79 6.4 5.5 61 5.93 ND 462 8 -Oct ND 6.41 7.23 6.7 _6.69 5.6 .36 5.97 ND 509 9 -Oct ND 7.04 8.05 6.64 _ND 6. 5.95 5.53 ND 769 10 -Oct ND 7.36 7.61 7.7 _ND ND 6.2 Ik95 6.65 ND 519 11 -Oct ND 7.17 7.59 7.63 ND 5.9 6.5 ND 528 12 -Oct ND 7.59 7.75 7.89 ND 5.6 5. ® 5.84 ND 539 13 -Oct ND 7.52 8.37 7.92 ND 5.4 6.48 96 ND 549 14 -Oct ND 6.46 8.12 6.87 ND 5.4 7.17 ND 539 15 -Oct ND 7.66 7.63 8.09 ND 5.4 k66.35 5. ND 539 16 -Oct ND 7.82 8.63 8.22 ND °° 5.4 F6.39 5.88 D 539 17 -Oct ND 7.15 8.6 7.61 ND 5.k 6.17 5.73 ND 509 18 -Oct ND 7.16 7.69 7.67 `'ND 5. 6.13 5.75 ND_ 480 19 -Oct ND 7.07 8.18 7.63 ND 5.3 66 5.86 ND 519 20 -Oct ND 7.06 58 7.6 ND 5.3 6.85 5.8 ND 519 21 -Oct ND 7.2 7.64 ND 6.1 7.35 6.05 ND 453 22 -Oct ND 7.9 7.27 8.33 ND 6.6 6.78 6.64 ND 453 23 -Oct ND 8.25 ND 9 ND 6.5 ND 7.05 ND 499 24 -Oct ND 7.91 ND 8.51 ND 6.2 ND 6.58 ND 509 25 -Oct ND 8.05 ND 8.6 ND 6.2 ND 6.53 ND 519 26 -Oct ND 8.33 ND 8.4 ND P 6.2 ND 6.49 ND 509 27 -Oct ND 8.25 ND 8.4 ND 6.1 ND 6.5 ND 471 28 -Oct ND 8.2 ND 8.56 ND 6.1 ND 6.38 ND 499 29 -Oct N8.16 ND 8.56 ND 5.7 ND 6.16 ND 471 30 -Oct N 8.09 ND 8.38 ND 5.8 ND 6.1 ND 499 31 -Oct ND 3 ND 7.77 ND 5.9 ND 6.18 ND 480 Appendix A - 7 Appendices Appendix A - 8 Dissolved Oxygen Daily Aveimge Dissolved Oxygen Daily Minimum Minimum Flow Date TZl TZ2 TZl TZ2 TZl 2008 2016 2008 2016 2008 2016 2008 2016 2008 2016 1 -Nov ND 8.04 ND 8.34 ND 5.9 ND 6.24 ND 453 2 -Nov ND 8.4 ND 8.72 ND 6 ND 6.35 ND 462 3 -Nov ND 8.73 ND 8.96 ND 6.2 ND 6.35 ND 462 4 -Nov ND 8.26 ND 8.42 ND 6.5 ND 6.75 ND 409 5 -Nov ND 8.41 ND 8.48 ND 6.9 ND 7.17 ND 462 6 -Nov ND 8.48 ND 8.67 ND 7.6 ND 7.38 ND 444 7 -Nov ND 8.71 ND 8.76 ND 7.6 ND 7.4 ND 401 8 -Nov ND 8.31 ND 8.36 ND 7 1,h) 7.02 ND 444 9 -Nov ND 8.52 ND 8.58 ND 7.3 ND 7.01 ND 385 10 -Nov ND 9.2 ND 8.97 ND 7.5 ND 7.16 ND 409 11 -Nov ND 8.82 ND 8.87 ND 7.8 ND 7.68 ND 435 12 -Nov ND 9.07 ND 9.28 ND 7.5 ND ® 7.59 ND 418 13 -Nov ND 8.63 ND 8.39 ND 7.6 ND JL7.4 ND 401 14 -Nov ND 8.44 ND 8.85 SID 7.2 ND 7.39 ND 401 15 -Nov ND 8.63 ND 8.48 ND 7.4 ND 7.16 ND 409 16 -Nov ND 9.05 ND 9.21 ND 7.2 ND 7.37 D 435 17 -Nov ND 9.21 ND 9.4 ND 7.5 ND 7.71 ND 409 18 -Nov ND 9.36 ND 9 D 7.4 ND 7.41 ND 426 19 -Nov ND 9.31 ND 9. 7.6 ND 7.66 ND 361 20 -Nov ND 9.63 D 9.9 ND 9 ND 7.73 ND 385 21 -Nov ND 9. 9.48 ND 9 ND 7.82 ND 377 22 -Nov ND 9. N 9.94 D 8.2 8.13 ND 385 23 -Nov ND 9. ND 10.13 ND 8.2 ND 8.41 ND 401 24 -Nov ND 9.45 ND 58 ND 8.2 ND 8.58 ND 393 25 -Nov ND 9.7 ND .06 ND 7.9 ND 7.78 ND 393 26 -Nov ND 9.83b, ND 10.14 ND 8.3 ND 7.77 ND 377 27 -Nov ND 10. 1,Q ND ht0.57 ND 8.6 ND 8.36 ND 435 28 -Nov ND 9.6 1 ND ND 8.1 ND 8.16 ND 426 29 -Nov ND 9.76 ND N984V-ND ND 8 ND 8.12 ND 377 30 -Nov ND 9.92 ND 8.9 ND 8.76 ND 369 Appendix A - 8 APPENDIXB TAXONOMIC LISTING OF BEN IC MACROINVERTEBRATES COLLECTED FROM SITES TZ1 AND TZ2 IN THE PEE DEE RIVER BELOW TILLERY DAM DURING JULY 2008 AND JULY 2016 AND THE TAXON'S ASSOCIATED BIOTIC INDEX CE VALUE (T.V.)1. 1 Appendix B - 1 Amnicola limosa Somatogyrus S 6Pleuroceridae Elimia catenaria Leptoxis sp. Viviparidae Campeloma decisi Basommatophora Aucylidae Ferrissia rivularis Laevapex fuscus Physidae Physella sp. Plauorbidae Helisoma anceps Menetus dilatatus C 1.7 A 5.8 A A A C R C R A C 6.6 R TZl TZ2 TAXA T.V. 2008 2016 2008 2016 Nemertea A R 6.6 A Tetrastemmatidae — — 7.6 — Prostoma graecense 6.6 R — — — PLATYHELMINTHES Turbellaria Tricladida Dugesiidae Girardia (Dugesia) tigrzna 7.1 A A A MOLLUSCA Bivalvia Veueroida Corbiculidae Corbicula fluminea 6.6 C C Sphaeriidae Musculium transversum <<<z — Pisidium sp.— Sphaerium sp. R R — Uuiouidae Elliptio compl a — A — Elliptio s < A — Villos mbis <<< — — Amnicola limosa Somatogyrus S 6Pleuroceridae Elimia catenaria Leptoxis sp. Viviparidae Campeloma decisi Basommatophora Aucylidae Ferrissia rivularis Laevapex fuscus Physidae Physella sp. Plauorbidae Helisoma anceps Menetus dilatatus C 1.7 A 5.8 A A A C R C R A C 6.6 R R 6.6 A — A — 8.7 A A A R 6.6 A — — — 7.6 — R — — Appendix B - 2 Cambaridae Cambarus hobbsor Cladocera Daphnidae Ceriodaphnia Daphnia lumholtzi Daphnia sp. Sidaidae Sida crystillina Isopoda Asellidae Caecidotea sp. Amphipoda <<<Z — <<<z — <<<z — <<<z — R R R R C A 8.4 A A A A Appendix B - 3 TZl TZ2 TAXA T.V. 2008 2016 2008 2016 ANNELIDA Clitellata Oligochaeta Tubificida Ilyodrilus templtont 9.3 — — R — Limnodrilus hoff neisteri 9.4 C — C — Naididae Naffs sp. 8.7 — R — Stylaria lacustris 8.4 R C — Tubificinae w.o.h.c. <<<Z A Quistadrilus multiisetosus <<<2 C Lumbriculida Lumbriculidae Lumbriculus sp. <<<2 A A Hirudinea Rhynchobdellida Glossiphoniidae Batrachobdella phalera < — R Erpobdellidae Erpobdella/Mooreobdella Helobdelll�la elongata <<< — — Helobdell�.triserialis 9.3 C Cambaridae Cambarus hobbsor Cladocera Daphnidae Ceriodaphnia Daphnia lumholtzi Daphnia sp. Sidaidae Sida crystillina Isopoda Asellidae Caecidotea sp. Amphipoda <<<Z — <<<z — <<<z — <<<z — R R R R C A 8.4 A A A A Appendix B - 3 ®Argia sp. Enallagma sp. Ischnura Gomphida Gomphus sp. Macromiidae Macromia sp. Coruliidae Neurocordulia obsoleta Megaloptera Corydalidae Corydalus cornutus Trichoptera A 9.5 — 5.9 — 6.2 — 5.3 R A — I R R R — C C A R 5.2 A C C C Appendix B - 4 TZl TZ2 TAXA T.V. 2008 2016 2008 2016 Hyalellidae Hyalella azteca 7.2 A A A A Insecta Ephemeroptera Baeiidae Baetis intercalaris 5 — C — C Heterocloeon sp. 3.7— Iswaeon anoka 4.4 — — A Labiobaetis ephippiatus 3.5 C A — Labiobaetis propinquus 5.8 — — A Plauditus sp. «<Z — R — Caenidae Caenis latipennis 6.8 — R Heptageniidae Maccafferfrum sp. <<<Z — — Macaffertium modestum 5 — A — Maccaffertium smithae — — A Stenacron interpunctatum 4 C — Stenacron sp. A Leptohyphidae Tricorythh�o,d�es albiline 5 — A Tricorythr7des robacki 5 — — A Tricorythodes 5 A A — Odonata ®Argia sp. Enallagma sp. Ischnura Gomphida Gomphus sp. Macromiidae Macromia sp. Coruliidae Neurocordulia obsoleta Megaloptera Corydalidae Corydalus cornutus Trichoptera A 9.5 — 5.9 — 6.2 — 5.3 R A — I R R R — C C A R 5.2 A C C C Appendix B - 4 TZl TZ2 TAXA T.V. 2008 2016 2008 2016 Glossosomatidae Protoptila sp. 2.3 — — — R Hydropsychidae Cheumatopsyche sp. 6.6 A A A A Hydropsyche bidens <<<Z — R — R Hydropsyche sp. <<<z R C — A Hydropsyche depravata gp. «<Z — C Hydropsyche venularis 5.1 — C — A Macrostemum carolina 3.4 — A C Hydroptilidae Hydroptila sp. 6.5 C C C Orthotrichia Sp. <<<Z R — Leptoceridae Ceraclea maculata 6.2 — — — Cerarlea sn 2.2 R — R C A R C C C R C PetrophiQ Coleopter Dytiscida Neopo Elmidae Ancyron Dubirapia sp. Macronychus glabratus Stenelmis crenata Psephenidae Psephenus herricki Hydrophilidae Berosus sp. Diptera .6 — C C A 5 C — R R 6.5 — — C — 5.5 R R 4.7 — — A C 7.8 C — R — 2.3 A — — — 8.8 — — R — Appendix B - 5 C C A A Hemerodromia sp. ` — R — R Simuliidae Simulium dLiciense g 4.9 — A — A Simulium vittatu 9.1 — C — R Simulium sp. 4.9 C — C — Tabanidae — R — — Tipulidae Tipula sp. 7.5 — — R R 'Tolerance values were adopted from (NCDEQ 2016) where: R — Rare (1-2 individuals collected) C — Common (3-9 individuals collected) A — Abundant (10 or more individuals collected) -- Not collected Appendix B - 6 TZl TZ2 TAXA T.V. 2008 2016 2008 2016 Chirouomidae Ablabesmyia mallochi 7.4 R C R A Ablabesmyia rhamphe gp. 6.8 ', R C R — Cardiocladius obscurus 4.4 — C — — Chironomus sp. 9.3 C R C A Cladotanytarsus sp. 4 — — R C Cricotopus sp. <<<Z C Cricotopus bicinctus 8.7 A A — Cricotopus triannulatus <<<Z — C — Cryptochironomus sp. 6.4 C R A — Dicrotendipes neomodestus 7.9 A — A Dicrotendipes fumidus 8.8 — — Orthocladius clarkei 5.6 — — Nanocladius distinctus 7.4 — R Pentaneura sp. <<<Z — R Polypedilum flavum .7 R A Polypedilum halterale — A — Polypedilum scalaenum gp. 8.5 A A Procladius sp. 8.8 — — R — Pseudochironomus sp. 4.9 R R Rheotarrytarsus exiguu 6.5 C A A Stenochironomus sp. 6.3 C A R C Synorthocladius semivi 4.2 R C — C C A A Hemerodromia sp. ` — R — R Simuliidae Simulium dLiciense g 4.9 — A — A Simulium vittatu 9.1 — C — R Simulium sp. 4.9 C — C — Tabanidae — R — — Tipulidae Tipula sp. 7.5 — — R R 'Tolerance values were adopted from (NCDEQ 2016) where: R — Rare (1-2 individuals collected) C — Common (3-9 individuals collected) A — Abundant (10 or more individuals collected) -- Not collected Appendix B - 6 z Specimens that were not listed in the NCDEQ 2016 Version 5.0 Tolerance Values for Genera and Species of Aquatic Macroinvertebrates (denoted with <<< for the tolerance value) were not included in the calculations of NCIBI values. Appendix B - 7