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Home My WebLink About2009-2010 Final ReportCOASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. NEW HANOVER COUNTY WATER QUALITY MONITORING PROGRAM 2009-2010 FINAL REPORT Prepared by: Coastal Planning & Engineering of North Carolina, Inc. Marine Scientist: Brad Rosov, M.Sc. Prepared For: New Hanover County, North Carolina Recommended Citation: Rosov, B., 2010. New Hanover County Water Quality Monitoring Program: 2009-2010 Final Report. New Hanover County, North Carolina: Coastal Planning & Engineering of North Carolina, Inc. 47p. July 2010 i COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. EXECUTIVE SUMMARY This report represents the June 2009 through May 2010 results of the New Hanover County Water Quality Monitoring Program. Nineteen (19) monitoring stations within seven (7) creeks in New Hanover County were monitored on a monthly basis for physical, chemical, and biological parameters of water quality. The results presented in this report are described from a watershed perspective. In order to provide a quick-glance assessment of the water quality within a particular sampling station and watershed, a rating system has been established for a number of parameters. This quantitative system assigns a rating of “GOOD”, “FAIR”, or “POOR” to a sampling station depending on the percentage of samples exceeding the State standard for dissolved oxygen, turbidity, Chlorophyll-a, Enterococci, and fecal coliform bacteria. If the recorded value of a parameter exceeds the State standard less than 10% of the times sampled, the station will receive a “GOOD” rating for the parameter. A “FAIR” rating is assigned when a parameter exceeds the State standard 11-25% of the times sampled. Parameters measured that exceed the State standard more than 25% of the sampling times are given a “POOR” rating. As displayed in the tables below, turbidity and Chlorophyll-a were determined to be “good” within all watersheds throughout the study period. Dissolved oxygen varied considerably between watersheds and within sites. Specifically, Barnards Creek, Lords Creek, Motts Creek, and Smith Creek were deemed to be “good” while Futch Creek contained “fair” levels of dissolved oxygen. Both Pages Creek and Prince Georges Creek were rated as “poor" for dissolved oxygen. Generally, Enterococci was problematic in a number of these watersheds. All watersheds were rated as “poor” with the exception of Futch Creek, which contained “good” levels. Fecal coliform, another indicator of bacterial contamination, was assessed monthly within Pages Creek and Futch Creek. These creeks generally exceeded the State shellfish standard for fecal coliform bacteria resulting in “poor ratings”. Ratings by Watershed Parameter Barnards Creek Futch Creek Lords Creek Motts Creek Pages Creek Prince Georges Creek Smith Creek Turbidity GOOD GOOD GOOD GOOD GOOD GOOD GOOD Dissolved Oxygen GOOD FAIR GOOD GOOD POOR POOR GOOD Chlorophyll-a GOOD GOOD GOOD GOOD GOOD GOOD GOOD Enterococci POOR GOOD POOR POOR POOR POOR POOR Fecal Coliform N/A POOR N/A N/A POOR N/A N/A ii COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. NEW HANOVER COUNTY WATER QUALITY MONITORING PROGRAM FINAL REPORT Table of Contents Introduction ........................................................................................................................................1 Parameters .......................................................................................................................................4 Standards .........................................................................................................................................6 Methods..............................................................................................................................................8 Physical Parameters ........................................................................................................................9 Chemical and Biological Parameters ..............................................................................................9 Results ................................................................................................................................................9 Rating System .................................................................................................................................9 Barnards Creek ................................................................................................................................10 Futch Creek .....................................................................................................................................13 Lords Creek .....................................................................................................................................17 Motts Creek .....................................................................................................................................20 Pages Creek .....................................................................................................................................24 Prince Georges ................................................................................................................................28 Smith Creek ....................................................................................................................................32 Comprehensive Rating by Watershed .............................................................................................37 Long Term Trends ..........................................................................................................................38 Discussion ..........................................................................................................................................43 Literature Cited ................................................................................................................................46 List of Figures Figure No. 1 Map of New Hanover County and watersheds included in this study ...................................3 2 Water Quality Sites within the Barnards Creek Watershed ...................................................11 3 Dissolved Oxygen at BC-CBR ..............................................................................................12 4 Dissolved Oxygen at BC-CBR ..............................................................................................12 5 Water Quality Sites with the Futch Creek Watershed ..................................................................14 6 Dissolved Oxygen at FC-4 .....................................................................................................15 7 Dissolved Oxygen at FC-6 .....................................................................................................15 8 Dissolved Oxygen at FC-13 ................................................................................................... 15 9 Dissolved Oxygen at FC-FOY ............................................................................................... 16 10 Enterococci and Fecal Coliform at FC-4 ............................................................................... 16 11 Enterococci and Fecal Coliform at FC-6 ............................................................................... 16 12 Enterococci and Fecal Coliform at FC-13 ............................................................................. 17 13 Enterococci and Fecal Coliform at FC-FOY ......................................................................... 17 14 Water Quality Site within the Lords Creek Watershed ......................................................... 19 15 Dissolved Oxygen at LC-RR ................................................................................................. 20 iii COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. NEW HANOVER COUNTY WATER QUALITY MONITORING PROGRAM FINAL REPORT Table of Contents (cont'd) List of Figures Figure No. 16 Enterococci Levels at LC-RR ............................................................................................20 17 Water Quality Sites within the Motts Creek Watershed ....................................................22 18 Dissolved Oxygen at MOT-CBR .......................................................................................23 19 Dissolved Oxygen at MOT-ND .........................................................................................23 20 Enterococci at MOT-CBR .................................................................................................23 21 Enterococci at MOT-ND ...................................................................................................24 22 Water Quality Sites within the Pages Creek Watershed ....................................................25 23 Dissolved Oxygen at PC-BDDS ........................................................................................26 24 Dissolved Oxygen at PC-BDUS ........................................................................................26 25 Dissolved Oxygen at PC-M ...............................................................................................27 26 Enterococci and Fecal Coliform at PC-BDDS ..................................................................27 27 Enterococci and Fecal Coliform at PC-BDUS ..................................................................27 28 Enterococci and Fecal Coliform at PC-M .........................................................................28 29 Water Quality Sites within the Prince Georges Creek Watershed .....................................29 30 Dissolved Oxygen at PG-CH .............................................................................................30 31 Dissolved Oxygen at PG-ML.............................................................................................30 32 Dissolved Oxygen at PG-NC .............................................................................................31 33 Enterococci at PG-CH .......................................................................................................31 34 Enterococci and Fecal Coliform at PG-ML .......................................................................31 35 Enterococci at PG-NC .......................................................................................................32 36 Water Quality Sites within the Smith Creek Watershed ....................................................33 37 Dissolved Oxygen at SC-23 ...............................................................................................34 38 Dissolved Oxygen at SC-CD .............................................................................................34 39 Dissolved Oxygen at SC-CH .............................................................................................35 40 Dissolved Oxygen at SC-GR .............................................................................................35 41 Dissolved Oxygen at SC-NK .............................................................................................35 42 Enterococci at SC-23 .........................................................................................................36 43 Enterococci at SC-CD ........................................................................................................36 44 Enterococci at SC-CH ........................................................................................................36 45 Enterococci at SC-GR ........................................................................................................37 46 Enterococci at SC-NK .......................................................................................................37 47 Long term dissolved oxygen data within Pages Creek ......................................................40 48 Long term dissolved oxygen data within Futch Creek ......................................................40 49 Long term dissolved oxygen data within Smith Creek ......................................................41 50 Long term turbidity data within Pages Creek ....................................................................41 51 Long term turbidity data within Futch Creek ....................................................................41 iv COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. NEW HANOVER COUNTY WATER QUALITY MONITORING PROGRAM FINAL REPORT Table of Contents (cont'd) List of Figures Figure No. 52 Long term turbidity data within Smith Creek ......................................................................... 42 53 Long term chlorophyll-a data within Pages Creek ........................................................................42 54 Long term chlorophyll-a data within Futch Creek .................................................................43 55 Long term chlorophyll-a data within Smith Creek ................................................................. 43 List of Tables Table No. 1 List of Sampling Sites ............................................................................................................2 2 North Carolina Water Quality Standards ...............................................................................7 3 Single sample standards for Enterococci as determined by the US EPA ..............................7 4 Single sample standards for Enterococci as determined by the NC DENR Recreational Water Quality Program ..........................................................................................................8 5 Proposed Tier Classification for New Hanover County Water Quality Monitoring Sampling Sites .......................................................................................................................8 6 Mean values of select parameters from Barnards Creek .......................................................11 7 Ratings of parameters within sampling stations within Barnards Creek ...............................12 8 Mean values of select parameters from Futch Creek .............................................................14 9 Ratings of parameters within sampling stations within Futch Creek ....................................17 10 Mean values of select parameters from Lords Creek .............................................................19 11 Ratings of parameters within sampling stations within Lords Creek ....................................20 12 Mean values of select parameters from Motts Creek .............................................................22 13 Ratings of parameters within sampling stations within Motts Creek ....................................24 14 Mean values of select parameters from Pages Creek .............................................................26 15 Ratings of parameters within sampling stations within Pages Creek ....................................28 16 Mean values of select parameters from Prince Georges Creek .............................................30 17 Ratings of parameters within sampling stations within Prince Georges Creek .....................32 18 Mean values of select parameters from Smith Creek ............................................................34 19 Ratings of parameters within sampling stations within Smith Creek ....................................37 20 Ratings of parameters within each watershed ........................................................................38 21 Changes of ratings within watersheds since 2007 .................................................................38 22 Enterococci levels in select sites between Nov. 2007 and May 2010 ...................................39 v COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. NEW HANOVER COUNTY WATER QUALITY MONITORING PROGRAM FINAL REPORT Table of Contents (cont'd) List of Appendices Appendix No. A Photographs of Sampling Sites B Raw Data 1 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. INTRODUCTION The creeks in New Hanover County, North Carolina provide a wide range of recreational activities for thousands of local citizens and visiting tourists each year. Tidal creeks are rich areas in terms of aquatic, terrestrial and avian wildlife and can support complex food webs (Odum et al, 1984; Kwak and Zedle, 1997). Protection of the water quality within these creeks is a high priority for New Hanover County. As growth and development continue within the City of Wilmington and the County, water quality has been increasingly threatened due to many factors including aging infrastructure, increased impervious surface area and subsequent stormwater runoff. To address these issues, the County has administered a long-standing water quality monitoring program since 1993 designed to assess the water quality within the creeks located within the County. Coastal Planning & Engineering of North Carolina, Inc. began monitoring seven (7) tidal creeks within New Hanover County on a monthly basis beginning in November 2007. The information presented in this report represents the results of this monitoring between the months of June 2009 and May 2010. The creeks included in this study are Pages and Futch Creek, which drain into the Atlantic Intracoastal Waterway (ICW) and Lords, Motts, Barnards, Smith, and Prince Georges Creek, which drain into the Cape Fear River (Figure 1) (Table 1). Thirteen (13) of the nineteen (19) sampling sites were previously monitored by the University of North Carolina at Wilmington. In order to assess any changes to historical trends within individual sites and entire watersheds, data provided by UNCW has been analyzed and incorporated into the results and discussion section of this report. Photographs of each sampling site are found in Appendix A. 2 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Table 1. List of Sampling Sites Creek Name Site Name Site Code Latitude Longitude Motts Creek Carolina Beach Road MOT-CBR 34° 08.610 77° 53.830 Motts Creek Normandy Drive MOT-ND 34° 08.373 77° 54.580 Lords Creek River Road LC-RR 34° 05.185 77° 55.275 Barnards Creek Carolina Beach Road BC-CBR 34° 09.522 77° 54.712 Smith Creek Castle Hayne Road SC-CH 34° 15.541 77° 56.325 Smith Creek 23rd Street SC-23 34° 15.472 77° 55.178 Smith Creek Candlewood Drive SC-CD 34° 17.438 77° 51.332 Smith Creek North Kerr SC-NK 34° 15.744 77° 53.256 Smith Creek Gordon Road SC-GR 34° 16.639 77° 52.037 Prince Georges Creek Marathon Landing PG-ML 34° 21.088 77° 55.349 Prince Georges Creek Castle Hayne Road PG-CH 34° 20.675 77° 54.217 Prince Georges Creek North College PG-NC 34° 20.331 77° 53.607 Futch Creek 4 FC-4 34° 18.068 77° 44.760 Futch Creek 6 FC-6 34° 18.178 77° 45.038 Futch Creek 13 FC-13 34° 18.214 77° 45.451 Futch Creek Foy Branch FC-FOY 34° 18.405 77° 45.358 Pages Creek Mouth PC-M 34° 16.209 77° 46.270 Pages Creek Bayshore Drive Down Stream PC-BDDS 34° 16.685 77° 47.673 Pages Creek Bayshore Drive Up Stream PC-BDUS 34° 16.623 77° 48.104 3 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 1. Map of New Hanover County and watersheds included in this study The State of North Carolina has employed a series of classifications that apply to all waters in the State including streams, rivers, and lakes (NC Administrative Code, section 15A NCAC 2B .0200). These classifications are meant to protect the specified uses within waterbodies. These include aquatic life survival and reproduction, secondary recreation, primary recreation, shellfishing, and water supply. The classifications that apply to the creeks examined in this study are: 4 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. C Sw: Freshwater that is protected for aquatic life and secondary recreation uses. The “Sw” supplemental classification indicates that these are swamp waters, and so are likely to have lower dissolved oxygen and pH than non-swamp streams due to natural conditions. However, a majority of the sites, including Lords Creek, Motts Creek, Barnards Creek, Smith Creek, and Prince Georges Creek, designated as C Sw by the State, are tidally influenced and have a brackish salinity range. SA: Saline water bodies that are protected for shellfishing uses. This use requires a more stringent standard for fecal coliform. Areas protected for shellfishing are also subject to the protection requirements for the less stringent classifications of SC and SB, which include aquatic life, secondary recreation, and primary recreation. This designation applies to Futch Creek and Pages Creek. Parameters Physical, chemical, and biological water quality monitoring data are currently being collected for this study. Physical parameters include temperature, salinity, conductivity, pH, turbidity, and dissolved oxygen. Chemical parameters monitored in this study include orthophosphate and nitrate/nitrite. Biological parameters include Chlorophyll-a and two suites of fecal indicator bacteria: Enterococci and fecal coliform bacteria. Due to limited funding, fecal coliform samples were only collected from sampling sites located within Futch Creek and Pages Creek. Temperature: Thermal pollution can result in significant changes to the aquatic environment. Most aquatic organisms are adapted to survive within a specific temperature range. Thermal pollution may also increase the extent to which fish are vulnerable to toxic compounds, parasites, and disease. If temperatures reach extremes of heat or cold, few organisms will survive. Thermal pollution may be caused by stormwater runoff from warm surfaces such as streets and parking lots. Soil erosion is another cause, since it can cause cloudy conditions in a water body. Cloudy water absorbs the sun's rays, resulting in a rise in water temperature. Thermal pollution may even be caused by the removal of trees and vegetation which normally shade the water body. In addition to the direct effects of thermal pollution on aquatic life, there are numerous indirect effects. Thermal pollution results in lowered levels of dissolved oxygen, since cooler water can hold more oxygen than warmer water. Salinity: Salinity is a measure of the amount of sodium chloride ions dissolved in water. This is important to monitor since changes in the levels of salt concentration can impact the ability of salt sensitive species to survive. An estuary, such as the lower Cape Fear River, usually exhibits a gradual change in salinity throughout its length, as freshwater entering the estuary from tributaries mixes with seawater moving in from the ocean. Salinity levels control, to a large degree, the types of plants and animals that can live in different zones of the estuary. Freshwater species may be restricted to the upper reaches of the estuary, while marine species inhabit the estuarine mouth. Some species tolerate only intermediate levels of salinity while broadly adapted species can acclimate to any salinity ranging from freshwater to seawater. 5 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Conductivity: Specific conductance is a measure of the ability of water to conduct an electrical current. Similar to salinity, it measures the amount of dissolved ions (including sodium chloride) in the water. pH: The pH of water is a measurement of the concentration of H+ ions, using a scale that ranges from 0 to 14. Natural water usually has a pH between 6.5 and 8.5. While there are natural variations in pH, many pH variations are due to human influences. Unanticipated decreases in pH could be indications of acid rain, runoff from acidic soils, or contamination by agricultural chemicals. Turbidity: Turbidity is the amount of particulate matter that is suspended in water. Turbidity measures the scattering effect that suspended solids have on light: the higher the intensity of scattered light, the higher the turbidity. During a rainstorm, particles from the surrounding land are washed into the river making the water a muddy brown color, indicating higher turbidity. Dissolved Oxygen: Dissolved oxygen (DO) refers to the volume of oxygen that is contained in water. Oxygen enters the water as rooted aquatic plants and algae undergo photosynthesis and as oxygen is transferred across the air-water interface. The amount of oxygen that can be held by the water depends on the water temperature, salinity, and pressure. Rapidly moving water, such as in a flowing stream, tends to contain a lot of dissolved oxygen, while stagnant water contains little. Oxygen levels are also affected by the diurnal (daily) cycle. Plants, such as rooted aquatic plants and algae produce excess oxygen during the daylight hours when they are photosynthesizing. During the dark hours they must use oxygen for life processes. Bacteria in water can consume oxygen as organic matter decays. Thus, excess organic material in waterbodies can cause oxygen deficits. Aquatic life can become stressed or die in stagnant water containing high levels of rotting, organic material in it, especially in summer, when dissolved-oxygen levels are at a seasonal low. Phosphates: Phosphorus is a nutrient required by all organisms for the basic processes of life. Phosphorus is a natural element found in rocks, soils and organic material. Phosphorus clings tightly to soil particles and is used by plants, so its concentration in clean waters is generally very low. However, phosphorus is used extensively in fertilizer and other chemicals, so it can be found in higher concentrations in areas of human activity. High levels in the water column can be detrimental to water quality as phosphates can cause algal blooms resulting in decreased dissolved oxygen levels. Orthophosphate is sometimes referred to as "reactive phosphorus." Orthophosphate is the most stable kind of phosphate, and is the form used by plants. Orthophosphate is produced by natural processes and is found in sewage. 6 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Nitrate/Nitrite: Nitrate is highly soluble (dissolves easily) in water and is stable over a wide range of environmental conditions. It is easily transported in streams and groundwater. Nitrates feed plankton (microscopic plants and animals that live in water), aquatic plants, and algae, which are then eaten by fish. Nitrite is relatively short-lived in water because it is quickly converted to nitrate by bacteria. Excessive concentrations of nitrate and/or nitrite can be harmful to humans and wildlife. If excessive amounts of nitrates are added to the water, algae and aquatic plants can be produced in large quantities. When these algae die, bacteria decompose them, and use up oxygen. Chlorophyll-a: Chlorophyll-a is a green pigment found in plants. It absorbs sunlight and converts it to sugar during photosynthesis. Chlorophyll-a concentrations are an indicator of phytoplankton abundance and biomass in coastal and estuarine waters. High levels often indicate an algal bloom which can induce the depletion of oxygen in the water column due to the microbial degradation of plant cells. Chlorophyll-a concentrations are often higher after rainfall, particularly if the rain has flushed nutrients into the water. Higher chlorophyll-a levels are also common during the summer months when water temperatures and light levels are high because these conditions lead to greater phytoplankton numbers. Fecal Coliform: Fecal Coliform bacteria are present in the feces and intestinal tracts of humans and other warm- blooded animals, and can enter water bodies from human and animal waste. If a large number of fecal coliform bacteria are found in water, it is possible that pathogenic (disease- or illness- causing) organisms are also present in the water. Pathogens are typically present in such small amounts it is impractical to monitor them directly. High concentrations of the bacteria in water may be caused by septic tank failure, poor animal keeping practices, pet waste, and urban runoff. In order to adequately assess human health risks and develop watershed management plans, it is necessary to know the sources of fecal contamination. Enterococci: Enterococci are distinguished from fecal coliform bacteria by their ability to survive in saltwater, and in this respect they more closely mimic many pathogens than do the other indicators. Enterococci are typically more human-specific than the larger fecal streptococcus group. EPA recommends Enterococci as the best indicator of health risk in saltwater used for recreation and as a useful indicator in freshwater as well. In 2004, Enterococci took the place of fecal coliform as the new federal standard for water quality at public beaches. It is believed to provide a higher correlation than fecal coliform with many of the human pathogens often found in sewage (Jeng, et al., 2004). Results indicated that Enterococci might be a more stable indicator than fecal coliform and, consequently, a more conservative indicator under brackish water conditions. Standards Water quality standards have been established legislatively for a number of these parameters (Table 2). Many of the water quality standards are described in the NC Administrative Code, section 15A NCAC 2H .0100. The water quality standards for Enterococci bacteria are 7 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. described by the US EPA (US EPA, 1986) and in the NC Administrative Code, section 15A NCAC 18A .3402. The US EPA standards for Enterococci bacteria are based on incidents of gastrointestinal illness following contact with bathing waters. Bacterial contamination is quantified by “colony forming units” or CFU. Single sample maximum allowable Enterococci density is 104 CFU/100ml, 158 CFU/100ml, 276 CFU/100ml, and 501 CFU/100ml for designated beach areas, swimming areas with moderate to full body contact, lightly used full body contact swimming areas, and infrequently used full body contact swimming areas, respectively (Table 3). When at least five samples are collected within a 30 day period, the US EPA recommends utilizing a geometric mean standard of 35 CFU/100ml. Geometric means are often useful summaries for highly skewed data, as are often found with bacteriological datasets. The North Carolina Recreational Water Quality Program (RWQ) adopted similar standards for Enterococci bacteria, also determined by the frequency of swimming activity. As defined by RWQ, Tier I swimming areas are used daily during the swimming season, Tier II swimming areas are used three days a week during the swimming season, and Tier III swimming areas are used on average 4 days a month during the swimming season. Single sample standards for Tiers I, II, and III are 104 CFU/100ml, 276 CFU/100ml, and 500 CFU/100ml, respectively (Table 4). A geometric mean of 35 CFU/100ml within Tier I swimming areas may also be utilized if at least five samples are collected within 30 days. The creeks included in this study have not been classified within the RWQ tier system; however an analysis of accessibility as an indicator of swimming and boating usage has been performed (Table 5). Based on this analysis, of the nineteen (19) sampling sites, three (3) could be considered Tier II and sixteen (16) could be considered Tier III. Table 2. North Carolina Water Quality Standards Parameter Standard for SA Waters Standard for C Sw Waters Dissolved Oxygen 5.0 mg/l 4.0 mg/la Turbidity 25 NTU 50 NTU pH 6.8-8.5 6.0-9.0b Chlorophyll-a 40.0 ug/l 40.0 ug/l Fecal Coliform Geometric Mean (5 samples within 30 days) <14 CFU/100ml; or 10% of samples <43 CFU/100ml Geometric Mean (5 samples within 30 days) <200 CFU/100ml; or single sample <400 CFU/100ml Enterococci c Geometric Mean (5 samples within 30 days) <35 CFU/100ml Geometric Mean (5 samples within 30 days) <35 CFU/100ml (a) Swamp waters may have lower values if caused by natural conditions (b) For swamp streams, pH may be as low as 4.3 if caused by natural conditions (c) See Table 4 for single sample standards based off the tiered system employed by NC DENR Recreational Water Quality Program Table 3. Single sample standards for Enterococci as determined by the US EPA Single sample maximum Designated beach areas < 104 CFU/100ml Swimming areas with moderate full body contact < 158 CFU/100ml Lightly used full body contact swimming areas < 276 CFU/100ml Infrequently used full body contact swimming areas < 501 CFU/100ml 8 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Table 4. Single sample standards for Enterococci as determined by the NC DENR Recreational Water Quality Program Single sample maximum Tier I, swimming areas used daily during the swimming season <104 CFU/100ml Tier II, swimming areas used three days a week during the swimming season <276 CFU/100ml Tier III, swimming areas used on average four days a month during the swimming season <500 CFU/100ml Table 5. Proposed Tier Classification for New Hanover County Water Quality Monitoring Sampling Sites Site Name Proposed Tier Classification Accessible for Boating or Swimming Comments MOT-CBR Tier III No Adjacent to culvert off Carolina Beach Road MOT-ND Tier III No Adjacent to small bridge on Normandy Drive LC-RR Tier III No Adjacent to bridge on River Road BC-CBR Tier III No Adjacent to culvert off Carolina Beach Road SC-CH Tier III No Adjacent to bridge on Castle Hayne Road SC-23 Tier III No Adjacent to bridge on 23rd Street SC-CD Tier III No Narrow, shallow. Adjacent to Candlewood Drive SC-NK Tier II Yes Small boat launch site off North Kerr SC-GR Tier III No Adjacent to culvert on Gordon Road PG-ML Tier III No Small boat launch site on private property PG-CH Tier III No Adjacent to culvert on Castle Hayne Road PG-NC Tier III No Adjacent to culvert on North College Road FC-4 Tier III No Private docks are the only means of direct access FC-6 Tier III No Private docks are the only means of direct access FC-13 Tier III No Private docks are the only means of direct access FC-FOY Tier III No No clear access points (no docks on Foy branch) PC-M Tier II Yes Direct access via docks and boat ramp at Pages Creek Marina PC-BDDS Tier III No Private docks are the only means of direct access PC-BDUS Tier II Yes Public boat ramp off Bayshore Drive METHODS The seven creeks included in this study were selected by County staff and individual sampling sites were selected by County staff in consultation with Coastal Planning & Engineering of North Carolina, Inc. These seven creeks are primarily located in the unincorporated portion of New 9 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Hanover County. Sampling sites were accessed from land, generally near a bridge or culvert crossing, or by boat. Each site was sampled one time per month during a high ebb tide. Tides were determined utilizing the National Oceanic and Atmospheric Administration’s (NOAA) Tides and Currents website (http://tidesandcurrents.noaa.gov/). Due to time constraints, monthly sampling events were conducted on three subsequent days each month. Lords Creek, Motts Creek, and Barnards Creek were visited on the first sampling day while Smith Creek and Prince Georges Creek were visited the second day. Futch Creek and Pages Creek were visited on the third day. Rainfall totals for the 24 hours prior to each sampling event were obtained from observations recorded at Wilmington International Airport as reported by NOAA’s National Weather Service web site (http://www.srh.noaa.gov/data/RAH/RTPRAH). Physical Parameters All physical measurements (temperature, salinity, conductivity, turbidity, dissolved oxygen, and pH) were taken in situ utilizing a 6820 YSI Multiparameter Water Quality Probe linked to a YSI 650 MDS display unit. The YSI Probe was calibrated each day prior to use. Physical measurements were taken from the surface at all sites (depth = 0.1m) and near the creek bottom at sites with depths greater than 0.5m. Following each sampling trip, the YSI Probe was post- calibrated following each sampling date to ensure that the physical parameters measured were within an acceptable range. Chemical and Biological Parameters Water samples were obtained for the laboratory analysis of chemical (nitrate/nitrite and orthophosphate) and biological (Enterococci, fecal coliform, and Chlorophyll-a) parameters. These grab samples were collected in sterile bottles during a high ebb tide from the surface at each site (depth = 0.1m). Water samples were placed on ice immediately following collection and were delivered in coolers to Environmental Chemists, Inc. of Wilmington, North Carolina for analysis. All analyses performed by Environmental Chemists, Inc. were conducted utilizing the following standard EPA approved methods: Orthophosphate: SM 4500E Nitrate/Nitrite: EPA 353.2 Chlorophyll-a: SM 10200H Fecal Coliform: SM 9222D Enterococci: EnterolertE RESULTS The results described in this report represent the physical, biological, and chemical data collected from all sampling sites on a monthly basis between June 2009 and May 2010. These results are organized by watershed. All raw data, including parameters not summarized in this section, are included in Appendix B. Rating System In order to provide a quick-glance assessment of the water quality within a particular sampling station or watershed, the University of North Carolina at Wilmington (UNCW) has previously employed a rating system for a number of parameters. This quantitative system assigns a rating 10 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. of “GOOD”, “FAIR”, or “POOR” to a sampling station depending on the percentage of samples exceeding the State standard for dissolved oxygen, turbidity, Chlorophyll-a, Enterococci, and fecal coliform bacteria. If the recorded value of a parameter exceeds the State standard less than 10% of the times sampled, the station will receive a “Good” rating for the parameter. A “Fair” rating is assigned when a parameter exceeds the State standard 11-25% of the times sampled. Parameters measured that exceed the State standard more than 25% of the sampling times are given a “Poor” rating. Barnards Creek The Barnards Creek watershed includes 4,953 acres and is located in the southwestern portion of the County, just along the City line. The watershed drains portions of Carolina Beach Road at its headwaters and flows towards River Road before entering into the Cape Fear River. Zoning within the watershed is comprised of a mix of residential and commercial uses. The land is classified as a mix of transition, urban, and conservation according to the CAMA land use plan. This watershed contains approximately 16.9% impervious surface coverage (Hume, 2009). Sampling was conducted at one site (BC-CBR) within the Barnards Creek watershed (Figure 2). Surface dissolved oxygen within BC-CBR ranged between 5.2 mg/l and 12.3 mg/l with a mean value of 7.7 mg/l. These values were within an acceptable level above the State standard of 4.0 mg/l for C Sw waters during all sampling events at both the surface and near the bottom of the water column (Figure 3). Chlorophyll-a ranged between 0.0 ug/l and 2.0 ug/l with a mean value of 0.9 ug/l at BC-CBR. These values did not approach the 40ug/l standard. Enterococci ranged between 64 CFU/100ml and 1,364 CFU/100ml with a geometric mean value of 426 CFU/100ml, which is above the NCDENR standard of 500 CFU/100ml for Tier III waters (Figure 4). Half of the samples (50%) exceeded this standard. Nitrate/nitrite levels ranged between 0.01 mg/l and 0.15 mg/l with a mean of 0.11 mg/l. Orthophosphate levels ranged between 0.01 mg/l and 0.02 mg/l with a mean of 0.01 mg/l. Turbidity values were generally good ranging between 0 and 27 NTU with a mean value of 7 NTU. No observations exceeded the State standard of 50 NTU for C SW waters. 11 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 2. Water Quality Sites within the Barnards Creek Watershed Table 6. Mean values of select parameters from Barnards Creek. Range in parentheses. Parameter BC-CBR Turbidity (NTU) 7 (0-27) Dissolved Oxygen (mg/l) 7.8 (5.4-12.3) Nitrate/Nitrite (mg/l) 0.11 (0.01-0.15) Orthophosphate (mg/l) 0.01 (0.01-0.02) Chlorophyll-a (ug/l) 0.9 (1.0-2.0) Enterococci (#CFU/100ml)425 (64-1364)1 (1)Enterococci values expressed as geometric mean 12 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 3. Dissolved Oxygen at BC-CBR Figure 4. Enterococci at BC-CBR Table 7. Ratings of parameters within sampling stations within Barnards Creek Parameter BC-CBR Turbidity GOOD Dissolved Oxygen GOOD Chlorophyll-a GOOD Enterococci POOR 13 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Futch Creek Futch Creek is located on the New Hanover-Pender County line and drains into the Intracoastal Waterway. The Futch Creek watershed encompasses approximately 3,136 acres extending from Scotts Hill Loop Road and Highway 17 on the north and east, to Porters Neck Road on the south. Zoning within the Futch Creek watershed is predominately residential with a small business district along Highway 17. The land within the Futch Creek watershed is classified as watershed resource protection or transition in the CAMA land use plan. This watershed contains approximately 11.0% impervious surface coverage (Hume, 2009). Sampling was conducted at four (4) sites (FC-4, FC-6, FC-13, and FC-FOY) within the Futch Creek watershed (Figure 5). Surface dissolved oxygen within the creek ranged between 3.9 mg/l and 10.1 mg/l with a mean value of 6.6 mg/l (Figures 6 through 9). Chlorophyll-a ranged between 1.0 ug/l and 15.0 ug/l with a mean value of 2.6 ug/l. None of these values approached the 40ug/l Chlorophyll-a standard. Enterococci ranged between 1 CFU/100ml and 9,000 CFU/100ml with a geometric mean value of 18 CFU/100ml. All samples collected within the four (4) sampling locations on December 1, 2009 exceeded the NCDENR Enterococci standard of 500 CFU/100ml for Tier III waters. Aside from those samples, no other exceedences were observed (Figures 10-13). The geometric mean of fecal coliform in Futch Creek was 18 CFU with a range of 1 to 1,546 CFUs. This geometric mean was above the NCDENR Shellfish Sanitation single-sample standard of 14 CFU/100ml. Twenty-three percent (23%) of all samples analyzed for fecal coliform levels exceeded 43 CFU/100ml. The State standard requires “no more than 10% of samples shall exceed 43 CFU/100ml)”. Nitrate/nitrite levels ranged between 0.01 mg/l and 0.08 mg/l with a mean of 0.02 mg/l. Orthophosphate levels ranged between 0.01 mg/l and 0.04 mg/l with a mean of 0.01 mg/l. Turbidity values were generally low ranging between 0 and 36 NTU with a mean value of 5 NTU. A total of 3 observations exceeded the State standard of 25 NTU for SA waters. 14 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 5. Water Quality Sites within the Futch Creek Watershed Table 8. Mean values of select parameters from Futch Creek. Range in parentheses. Parameter FC-4 FC-6 FC-13 FC-FOY Turbidity (NTU) 3 (0-17) 3 (0-15) 7 (0-36) 6 (0-31) Dissolved Oxygen (mg/l) 7.0 (4.4-10.1) 6.9 (4.4-10.1) 6.2 (3.4-10.4) 6.3 (3.3-9.8) Nitrate/Nitrite (mg/l) 0.01 (0.01-0.01)0.01 (0.01-0.01)0.02 (0.01-0.07) 0.02 (0.01-0.08) Orthophosphate (mg/l) 0.01 (0.01-0.01)0.01 (0.01-0.02)0.02 (0.01-0.04) 0.01 (0.01-0.03) Chlorophyll-a (ug/l) 2.0 (0.0-4.0) 2.0 (1.0-4.0) 3.9 (1.0-15.0) 2.6 (1.0-5.0) Enterococci (#CFU/100ml) 11 (1-728)1 10 (1-728)1 34 (5-9000)1 27 (5-3600)1 Fecal Coliform (#CFU/100ml) 13 (1-310)1 10 (1-260)1 39 (5-1455)1 20 (1-1546)1 (1)Enterococci and Fecal Coliform values expressed as geometric mean 15 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 6. Dissolved Oxygen at FC-4 Figure 7. Dissolved Oxygen at FC-6 Figure 8. Dissolved Oxygen at FC-13 16 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 9. Dissolved Oxygen at FC-FOY Figure 10. Enterococci and Fecal Coliform at FC-4 Figure 11. Enterococci and Fecal Coliform at FC-6 17 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 12. Enterococci and Fecal Coliform at FC-13 Figure 13. Enterococci and Fecal Coliform at FC-FOY Table 9. Ratings of parameters within sampling stations within Futch Creek Parameter FC-4 FC-6 FC-13 FC-FOY Turbidity GOOD GOOD GOOD GOOD Dissolved Oxygen GOOD FAIR POOR POOR Chlorophyll-a GOOD GOOD GOOD GOOD Enterococci GOOD GOOD GOOD GOOD Fecal Coliform POOR FAIR POOR POOR Lords Creek The Lords Creek Watershed is located in the southwestern portion of the County and encompasses approximately 3,047 acres. Zoning within the watershed is completely residential. This watershed contains approximately 12.6% impervious surface coverage (Hume, 2009). According to the CAMA land use plan, the land in the watershed is classified as a mix of conservation, transition, watershed resource protection and a small natural heritage resource 18 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. protection designation. Sampling was conducted at one (1) site (LC-RR) within the Lords Creek watershed (Figure 14). Mean values and ratings from this site are presented in Tables 10 and 11. Surface dissolved oxygen LC-RR ranged between 3.4 mg/l and 12.1 mg/l with a mean value of 7.7 mg/l. With the exception of the data collected in September 2009, these values were within an acceptable level above the State standard of 4.0 mg/l for C Sw waters during both the surface and near the bottom of the water column (Figure 15). Chlorophyll-a ranged between 1.0 ug/l and 26.0 ug/l with a mean value of 14.3 ug/l. Samples obtained in August 2009 exceeded the State standard of 40ug/l for Chlorophyll-a. Enterococci ranged between 5 CFU/100ml and 470 CFU/100ml with a geometric mean value of 58 CFU/100ml. No individual samples contained high levels of Enterococci beyond the NCDENR standard of 500 CFU/100ml for Tier III waters (Figure 16). Nitrate/nitrite levels ranged between 0.01 mg/l and 0.51 mg/l with a mean of 0.19 mg/l. Orthophosphate levels ranged between 0.01 mg/l and 0.10 mg/l with a mean of 0.02mg/l. Turbidity values were generally moderate ranging between 4 and 37 NTU with a mean value of 14 NTU. No observations exceeded the State standard of 50 NTU for C Sw waters in Lords Creek during the study period. 19 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 14. Water Quality Site within the Lords Creek Watershed Table 10. Mean values of select parameters from Lords Creek. Range in parentheses. Parameter LC-RR Turbidity (NTU) 14 (4-37) Dissolved Oxygen (mg/l) 7.7 (3.4-12.1) Nitrate/Nitrite (mg/l) 0.19 (0.01-0.51) Orthophosphate (mg/l) 0.02 (0.01-0.10) Chlorophyll-a (ug/l) 14.3 (1.0-26.0) Enterococci (#CFU/100ml)58 (5-470)1 (1)Enterococci values expressed as geometric mean 20 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 15. Dissolved Oxygen at LC-RR Figure 16. Enterococci Levels at LC-RR Table 11. Ratings of parameters within sampling stations within Lords Creek Parameter LC-RR Turbidity GOOD Dissolved Oxygen GOOD Chlorophyll-a GOOD Enterococci GOOD Motts Creek Motts Creek watershed encompasses approximately 2,389 acres and is located in the southwestern portion of the County, just below Sanders Road. The Creek drains portions of Carolina Beach Road at its headwaters and then drains toward River Road before entering into the Cape Fear River. Zoning in the watershed is predominately residential with commercial business districts along Carolina Beach Road. Land in the watershed is classified as transition, conservation or wetland resource protection according to the CAMA land use plan. This watershed contains approximately 12.6% impervious surface coverage (Hume, 2009). Sampling 21 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. was conducted at two (2) sites (MOT-CBR, MOT-ND) within the Motts Creek watershed between the months of June 2009 and May 2010 (Figure 17). The select results from these individual stations are presented in Figures 18 through 21 and Tables 12 and 13. Surface dissolved oxygen within Motts Creek ranged between 1.6 mg/l and 12.3 mg/l with a mean value of 6.9 mg/l (Figures 18 and 19). Chlorophyll-a ranged between 0.0 ug/l and 7.0 ug/l with a mean value of 2.0 ug/l. These values did not approach the 40ug/l standard. Enterococci ranged between 10 CFU/100ml and 24,000 CFU/100ml with a geometric mean value of 455 CFU/100ml. MOT-ND and MOT-CBR each exceeded the NCDENR standard of 500 CFU/100ml for Tier III waters during five (5) and seven (7) of the twelve (12) times they were samples, respectively (Figures 20 and 21). Nitrate/nitrite levels ranged between 0.01 mg/l and 0.28 mg/l with a mean of 0.11 mg/l. Orthophosphate levels ranged between 0.01 mg/l and 0.08 mg/l with a mean of 0.02 mg/l. Turbidity values were generally good ranging between 2 and 30 NTU with a mean value of 11 NTU. No turbidity observations exceeded the State standard of 50 NTU for C Sw waters. 22 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 17. Water Quality Sites within the Motts Creek Watershed Table 12. Mean values of select parameters from Motts Creek. Range in parentheses. Parameter MOT-CBR MOT-ND Turbidity (NTU) 11 (2-30) 10 (3-20) Dissolved Oxygen (mg/l) 6.8 (1.6-12.9) 6.9 (1.9-12.3) Nitrate/Nitrite (mg/l) 0.1 (0.01-0.25) 0.12 (0.01-0.28) Orthophosphate (mg/l) 0.02 (0.01-0.06) 0.03 (0.01-0.08) Chlorophyll-a (ug/l) 2.3 (0.0-7.0) 1.8 (0.0-6.0) Enterococci (#CFU/100ml)327 (10-15000)1 634 (55-24000)1 (1)Enterococci values expressed as geometric mean 23 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 18. Dissolved Oxygen at MOT-CBR Figure 19. Dissolved Oxygen at MOT-ND Figure 20. Enterococci at MOT-CBR 24 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 21. Enterococci at MOT-ND Table 13. Ratings of parameters within sampling stations within Motts Creek Parameter MOT-CBR MOT-ND Turbidity GOOD GOOD Dissolved Oxygen FAIR GOOD Chlorophyll-a GOOD GOOD Enterococci POOR POOR Pages Creek Located in northeastern New Hanover County and encompassing 2,044 acres, Pages Creek watershed drains into the Intracoastal Waterway, north of Middle Sound Loop Road. Zoning within the Pages Creek watershed is predominately residential, with commercial zoning along Highway 17. The land within the Pages Creek watershed is predominately classified as watershed resource protection and conservation, with a small portion classified as transitional according to the CAMA land use plan. This watershed contains approximately 23.2% impervious surface coverage (Hume, 2009). Sampling was conducted at three (3) sites (PC- BDDS, PC-BDUS, and PC-M) within the Motts Creek watershed (Figure 22). Mean values and ratings from all individual sites are presented in Tables 14 and 15. Surface dissolved oxygen within Pages Creek ranged between 3.5 mg/l and 10.4 mg/l with a mean value of 6.6 mg/l. While dissolved oxygen at PC-M was acceptable during all sampling events, the dissolved oxygen within PC-BDDS and PC-BDUS were lower than the State standard of 5.0 mg/l for SA waters on numerous occasions (Figures 23 through 25). Chlorophyll-a ranged between 1.0 ug/l and 69.0 ug/l with a mean value of 6.3 ug/l. One sample collected from PC-BDUS, exceeded the State standard of 40 ug/l for Chlorophyll-a. Enterococci ranged between 4 CFU/100ml and 26,000 CFU/100ml with a geometric mean value of 185 CFU/100ml (Figures 26 through 28). While samples collected from PC-M did not contain high levels of Enterococci, five (5) and seven (7) samples from PC-BDDS and PC- BDUS, respectively, contained levels higher than the NCDENR standards. 25 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Fecal coliform levels ranged between 1 CFU/100ml and 9,000 CFU/100ml with a geometric mean of 160 CFU/100ml. Fecal coliform levels exceeded the NCDENR Shellfish Sanitation single-sample standard of 14 CFU/100ml on all twelve (12) sampling events at PC-BDDS and PC-BDUS. This standard was breached at PC-M on five (5) occasions (Figures 26 through 28). Sixty-nine percent (69%) of all samples analyzed for fecal coliform levels exceeded 43 CFU/100ml. The State standard allows “no more than 10% of samples shall exceed 43 CFU/100ml”. Nitrate/nitrite levels ranged between 0.01 mg/l and 0.08 mg/l with a mean of 0.02 mg/l. Orthophosphate levels ranged between 0.01 mg/l and 0.23 mg/l with a mean of 0.03 mg/l. Turbidity values were generally good ranging between 0 and 24 NTU with a mean value of 7 NTU. None of the observed turbidity values exceeded the State standard of 25 NTU for class SA waters. Figure 22. Water Quality Sites within the Pages Creek Watershed 26 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Table 14. Mean values of select parameters from Pages Creek. Range in parentheses. Parameter PC-BDUS PC-BDDS PC-M Turbidity (NTU) 9 (0-24) 7 (0-23) 5 (0-22) Dissolved Oxygen (mg/l) 6.5 (3.5-10.4) 6.5 (3.6-10.2) 7.0 (5.1-10.2) Nitrate/Nitrite (mg/l) 0.02 (0.01-0.05) 0.02 (0.01-0.08) 0.01 (0.01-0.01) Orthophosphate (mg/l) 0.06 (0.02-0.23) 0.02 (0.01-0.04) 0.01 (0.01-0.02) Chlorophyll-a (ug/l) 9.3 (1.0-69.0) 6.8 (1.0-24.0) 2.9 (1.0-5.0) Enterococci (#CFU/100ml) 889 (109-19000)1 356 (18-26,000)1 20 (4-480)1 Fecal Coliform (#CFU/100ml) 310 (73-8000)1 380 (18-9,000)1 12 (1-390)1 (1)Enterococci and Fecal Coliform values expressed as geometric mean Figure 23. Dissolved Oxygen at PC-BDDS Figure 24. Dissolved Oxygen at PC-BDUS 27 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 25. Dissolved Oxygen at PC-M Figure 26. Enterococci and Fecal Coliform at PC-BDDS Figure 27. Enterococci and Fecal Coliform at PC-BDUS 28 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 28. Enterococci and Fecal Coliform at PC-M Table 15. Ratings of parameters within sampling stations within Pages Creek Parameter PC-BDDS PC-BDDS PC-M Turbidity GOOD GOOD GOOD Dissolved Oxygen POOR POOR GOOD Chlorophyll-a GOOD GOOD GOOD Enterococci POOR POOR GOOD Fecal Coliform POOR POOR POOR Prince Georges Prince Georges Creek drains into the Cape Fear River. The Prince Georges Creek watershed is approximately 14,589 acres and drains most of Castle Hayne, extending eastward across I-40 into the Blue Clay Road area. Zoning within the Prince Georges Creek watershed is predominately residential with some business and light industrial districts within Castle Hayne. Most of the land within the Prince Georges Creek watershed is classified as aquifer resource protection, conservation or transition according to the CAMA land use plan. This watershed contains approximately 10.1% impervious surface coverage (Hume, 2009). Sampling was conducted at three (3) sites (PG-CH, PG-ML, and PG-NC) within the Prince Georges Creek watershed (Figure 29). Mean values and ratings from all individual sites are presented in Tables 16 and 17. Surface dissolved oxygen within Prince Georges Creek ranged between 0.6 mg/l and 12.6 mg/l with a mean value of 5.1 mg/l. Surface dissolved oxygen values at PG-CH and PG-NC were below the State standard of 4.0 mg/l for C Sw during six (6) sampling events each, while PG-ML was below the standard on five (5) occasions (Figures 30 through 32). Chlorophyll-a ranged between 00. ug/l and 20.0 ug/l with a mean value of 2.8 ug/l. These values did not exceed the 40ug/l standard. Enterococci ranged between 5 CFU/100ml and 47,000 CFU/100ml with a geometric mean value of 327 CFU/100ml. During this study, four (4) and seven (7) samples from PG-CH and PG-ML, 29 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. respectively, contained Enterococci levels above the NCDENR standard of 500 CFU/100ml for Tier III waters. Two (2) samples from PG-NC exceeded this value during the same time period (Figures 33 through 35). Nitrate/nitrite levels ranged between 0.01 mg/l and 0.50 mg/l with a mean of 0.11 mg/l. Orthophosphate levels ranged between 0.01 mg/l and 0.05 mg/l with a mean of 0.02 mg/l. Turbidity values were generally good ranging between 0 and 34 NTU with a mean value of 6 NTU. No observed turbidity values exceeded the State standard of 50 NTU for C Sw waters. Despite relatively low turbidity levels, the surface water at PG-NC appeared uncharacteristically discolored during the April and May 2010 sampling events. Water samples were examined by UNCW researchers and found to contain high levels of fungal hyphae, protozoans, and Euglenophyta algae. Euglenoids are considered to be characteristic of polluted water (Mallin, pers. comm.). Figure 29. Water Quality Sites within the Prince Georges Creek Watershed 30 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Table 16. Mean values of select parameters from Prince Georges Creek. Range in parentheses. Parameter PG-CH PG-ML PG-NC Turbidity (NTU) 5 (0-34) 3 (0-11) 10 (0-27) Dissolved Oxygen (mg/l) 5.0 (0.9-12.4) 5.9 (3.2-12.6) 4.4 (0.6-12.0) Nitrate/Nitrite (mg/l) 0.11 (0.01-0.26) 0.11 (0.01-0.29) 0.12 (0.01-0.50) Orthophosphate (mg/l) 0.02 (0.01-0.05) 0.04 (0.02-0.05) 0.01 (0.01-0.03) Chlorophyll-a (ug/l) 1.9 (0.0-5.0) 2.8 (0.0-13.0) 3.6 (0.0-20.0) Enterococci (#CFU/100ml) 370 (37-16,000)1 671 (208-1,910)1 140 (5-47,000)1 (1)Enterococci values expressed as geometric mean Figure 30. Dissolved Oxygen at PG-CH Figure 31. Dissolved Oxygen at PG-ML 31 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 32. Dissolved Oxygen at PG-NC Figure 33. Enterococci at PG-CH Figure 34. Enterococci and Fecal Coliform at PG-ML 32 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 35. Enterococci at PG-NC Table 17. Ratings of parameters within sampling stations within Prince Georges Creek Parameter PG-CH PG-ML PG-NC Turbidity GOOD GOOD GOOD Dissolved Oxygen POOR POOR POOR Chlorophyll-a GOOD GOOD GOOD Enterococci POOR POOR FAIR Smith Creek Located in north-central New Hanover County and containing approximately 14,665 acres, the Smith Creek watershed drains into the lower northeast Cape Fear River, just north of the Isabelle Holmes Bridge. The watershed drains land within the City limits and the unincorporated County, including the Wilmington International Airport. Zoning within the Smith Creek watershed is a mix of industrial, residential, and commercial. The land within the watershed is predominately classified as urban and transition, with a small portion classified as conservation. This watershed contains approximately 21.9% impervious surface coverage (Hume, 2009). Along with increased development and impervious surfaces, water quality in Smith Creek has declined in recent years. High bacteria levels have been reported, as well as low dissolved oxygen levels. As a result, Smith Creek has been listed on the 303(d) list for impaired waters due to impaired biological integrity. Sampling was conducted at five (5) sites (SC-CH, SC-23, SC-NK, SC-GR, SC-CD) within the Smith Creek watershed (Figure 36). Mean values and ratings from all individual sites are presented in Tables 18 and 19. Surface dissolved oxygen within the creek ranged between 3.8 mg/l and 13.5 mg/l with a mean value of 8.0 mg/l. With the exception of one observation from SC-NK August 2009, these values were within an acceptable level above the State standard of 4.0 mg/l for C Sw waters (Figures 37 through 41). Chlorophyll-a ranged between 1.0 ug/l and 26.0 ug/l with a mean value of 5.0 ug/l. All samples were within the acceptable range. 33 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Enterococci ranged between 10 CFU/100ml and 57,000 CFU/100ml with a geometric mean value of 593 CFU/100ml. A number of samples exceeded the NCDENR standard of 500 CFU/100ml for Tier III waters including two (2) from SC-23, ten (10) from SC-CD, eight (8) from SC-GR, and three (3) from SC-CH. Seven (7) samples from SC-NK exceeded the NCDENR standard of 276 CFU/100ml for Tier II waters (Figures 42 through 46). Nitrate/nitrite levels ranged between 0.01 mg/l and 0.72 mg/l with a mean of 0.16 mg/l. Orthophosphate levels ranged between 0.01 mg/l and 0.10mg/l with a mean of 0.03 mg/l. Turbidity values were generally good ranging between 0 and 118 NTU with a mean value of 11 NTU. Two (2) turbidity values from SC-CD exceeded the State standard of 50 NTU for SW class C waters. Figure 36. Water Quality Sites within the Smith Creek Watershed 34 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Table 18. Mean values of select parameters from Smith Creek. Range in parentheses. Parameter SC-23 SC-CD SC-CH SC-GR SC-NK Turbidity (NTU) 11 (4.0-32.0) 19 (0.0-118.0) 15 (2.0-33.0) 6 (0.0-23.0) 5 (0.0-21.0) Dissolved Oxygen (mg/l) 8.4 (4.5-13.4) 8.9 (6.2-13.4) 7.1 (4.1-13.5) 8.9 (5.6-12.6) 6.8 (3.8-12.5) Nitrate/Nitrite (mg/l) 0.17 (0.01-0.37) 0.08 (0.01-0.16) 0.28 (0.04-0.72) 0.13 (0.01-0.49) 0.14 (0.01-.038) Orthophosphat e (mg/l) 0.05 (0.03-0.08) 0.02 (0.01-0.04) 0.06 (0.04-0.08) 0.02 (0.01-0.10) 0.02 (0.01-0.05) Chlorophyll-a (ug/l) 9.8 (1.0-26.0) 4.8 (1.0-15.0) 4.1 (1.0-11.0) 2.2 (1.0-10.0) 3.9 (1.0-10.0) Enterococci (#CFU/100ml) 210 (10-39,000)1 2,084 (64-19,000)1 140 (19-57,000)1 1,106 (220- 23,000)1 1,089 (118- 38,000)1 (1)Enterococci values expressed as geometric mean Figure 37. Dissolved Oxygen at SC-23 Figure 38. Dissolved Oxygen at SC-CD 35 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 39. Dissolved Oxygen at SC-CH Figure 40. Dissolved Oxygen at SC-GR Figure 41. Dissolved Oxygen at SC-NK 36 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 42. Enterococci at SC-23 Figure 43. Enterococci at SC-CD Figure 44. Enterococci at SC-CH 37 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 45. Enterococci at SC-GR Figure 46. Enterococci at SC-NK Table 19. Ratings of parameters within sampling stations within Smith Creek Parameter SC-23 SC-CD SC-CH SC-GR SC-NK Turbidity FAIR GOOD GOOD GOOD GOOD Dissolved Oxygen GOOD GOOD GOOD GOOD GOOD Chlorophyll-a GOOD GOOD GOOD GOOD GOOD Enterococci FAIR POOR FAIR POOR POOR Comprehensive Rating by Watershed When combining all results from each site within individual watersheds, it is possible to obtain a “snapshot” of water quality within each watershed (Table 20). Barnards Creek demonstrates “good” water quality with the exception of Enterococci, which was in the “poor” category. Futch Creek has also shown to contain good ratings; however dissolved oxygen was shown to be “fair” while fecal coliform was determined to be “poor”. Both Lords Creek and Motts Creek were deemed “good” for all parameters with the exception of “poor” for Enterococci. Pages Creek also demonstrated “good” ratings for turbidity Chlorophyll-a, however dissolved oxygen, fecal coliform, and Enterococci were “poor”. Similar to Pages Creek, Prince Georges Creek had 38 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. “good” ratings for turbidity and Chlorophyll-a and “poor” ratings for dissolved oxygen and Enterococci. Smith Creek had “good” water quality for all parameters with the exception of Enterococci, which was rated as “poor”. Table 20. Ratings of parameters within each watershed Parameter Barnards Creek Futch Creek Lords Creek Motts Creek Pages Creek Prince Georges Creek Smith Creek Turbidity GOOD GOOD GOOD GOOD GOOD GOOD GOOD Dissolved Oxygen GOOD FAIR GOOD GOOD POOR POOR GOOD Chlorophyll-a GOOD GOOD GOOD GOOD GOOD GOOD GOOD Enterococci POOR GOOD POOR POOR POOR POOR POOR Fecal Coliform N/A POOR N/A N/A POOR N/A N/A Long Term Trends The rating system, based upon the number of samples exceeding State Standards, has been utilized to assess the “state” of the watersheds on an annual basis since the release of the 2008 Final Report. Since that time, the condition of several parameters has changed within select watersheds indicating emerging long term trends. Table 21 depicts these net changes since that time. A “+1” was ascribed if the parameter improved by a magnitude of one rating (i.e. from “fair” to “good”). If the magnitude of change increased by a magnitude of two ratings (i.e. from “poor” to “good”), the parameter was ascribe “+2”. A negative change (decline in water quality) was denoted with a negative sign. As depicted in Table 21, the turbidity ratings within all creeks have maintained a “good” rating. Similarly, Chlorphyll-a ratings have been “good” for all creeks with the exception of a change from “fair to “good” within Lords Creek. Motts Creek improved its dissolved oxygen rating from “fair” to “good”, while Prince Georges Creek has declined in dissolved oxygen levels (from “fair” to “poor”). The Enterococci levels have declined to “poor” ratings for Barnards Creek, Lords Creek, Motts Creek, and Prince Georges Creek. Barnards Creek and Motts Creek were rated as “good” in previous years while Lords Creek and Prince Georges Creek were formerly deemed “fair”. No changes of fecal coliform bacteria levels were observed within Futch Creek and Pages Creek (the only watersheds monitored for fecal coliform). Table 21. Changes of ratings within watersheds since 2007. Parameter Barnards Creek Futch Creek Lords Creek Motts Creek Pages Creek Prince Georges Creek Smith Creek Turbidity - - - - - - - Dissolved Oxygen - - - +1 - -1 - Chlorophyll-a - - +1 - - - - Enterococci -2 - -1 -2 - -1 - Fecal Coliform N/A - N/A N/A - N/A N/A In light of the apparent long term decline in water quality in terms of Enterococci levels within a number of the watersheds assessed, a closer examination of the results from individual sites was conducted. Table 22 depicts the long term results (since November of 2007) of Enterococci 39 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. samples within the ten individual sites containing the most violations of the State standard. Highlighted cells represent sample results which exceeded the State standard for Enterococci. The site exceeding the standard most often was SC-CD (Smith Creek at Candlewood Drive). This site exceeded the standard eighty-one (81%) of the time. Other sites exceeded this standard 29-52% of the times sampled. Table 22. Enterococci levels in select sites between Nov. 2007 and May 2010. Date SC-CD MOT-ND PC-BDDS PC-BDUS SC-GR BC-CBR PG-ML MOT-CBR SC-NK PG-CH Nov. 2007 517 819 548 135 250 88 378 56 99 281 Dec. 2007 1210 1414 727 517 139 43 57 10 238 135 Jan. 2008 41 129 238 133 53 56 1210 135 122 75 Feb. 2008 703 155 637 1542 345 122 52 171 860 30 March 2008 708 272 20 30 275 145 187 31 41 52 April 2008 663 142 3873 1935 146 63 122 663 121 107 May 2008 384 262 331 160 435 548 1106 75 7701 2247 June 2008 2010 275 41 30 96 134 201 144 41 109 July 2008 1700 201 15 350 290 800 480 128 91 210 Aug. 2008 109 275 208 46 1637 728 1182 819 127 819 Sept. 2008 728 546 19 109 163 510 10 310 154 290 Oct. 2008 1182 1455 745 195 1455 350 163 280 118 10 Nov. 2008 4700 910 728 64 5900 2300 3000 2800 2000 1546 Dec.2008 280 2600 560 91 290 1000 190 1728 91 364 Jan. 2009 7000 1091 819 530 6000 818 637 580 364 1182 Feb. 2009 1091 273 637 590 540 270 240 154 181 82 March 2009 1546 330 270 109 230 210 250 240 200 37 April 2009 630 1091 28 46 600 145 154 260 55 73 May 2009 21000 1728 637 60000 4000 1273 2800 2800 728 200 June 2009 4300 24000 25000 2100 3200 1160 1637 15000 290 1637 July 2009 18000 3900 1182 8000 23000 1364 1910 3300 38000 16000 Aug. 2009 19000 330 18 500 880 470 920 590 4200 96 Sept. 2009 2546 1000 235 819 480 560 1819 910 2000 1819 Oct. 2009 4600 637 280 4400 530 64 220 300 510 470 Nov. 2009 2400 210 118 819 1182 181 1455 109 400 1273 Dec. 2009 1546 595 26000 19000 5400 430 510 220 1819 728 Jan. 2010 54 910 19 388 220 637 1091 10 118 55 Feb. 2010 1273 290 100 230 380 1091 390 181 4900 109 March 2010 109 82 910 109 440 181 300 19 370 55 April 2010 1182 55 610 230 530 260 370 430 260 37 May 2010 10000 1455 37 230 1637 520 208 520 1455 270 % Above Standard 81% 52% 48% 48% 48% 45% 42% 36% 36% 29% 40 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Geometric Mean 1257 541 285 388 645 331 401 272 390 227 Std. Dev. 5691 4251 6283 11125 4276 509 798 2727 6863 2855 Long-term water quality monitoring data from select sites and watersheds was mined from the University of North Carolina at Wilmington to determine quantitative changes over time. Data was not available from all currently monitored stations; therefore this analysis was performed only for the stations which spanned the time period between 2004 and 2010. These included samples acquired from Smith Creek, Futch Creek, and Pages Creek. Figures 47 through 49 depicts the average level of dissolved oxygen within these creeks since 2004. As illustrated in these figures, the dissolved oxygen levels during the 2007 sampling period markedly declined within all three watersheds. Figure 47- Long term dissolved oxygen data within Pages Creek Figure 48- Long term dissolved oxygen data within Futch Creek 41 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 49- Long term dissolved oxygen data within Smith Creek Figures 50 through 52 depicts the trend of turbidity within Pages Creek, Futch Creek, and Smith Creek. As shown below, turbidity displayed an increase in magnitude during 2007. Figure 50- Long term turbidity data within Pages Creek Figure 51- Long term turbidity data within Futch Creek 42 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 52- Long term turbidity data within Smith Creek Chlorophyll-a levels within Pages Creek have increased since 2004 reaching an annual maximum in 2008 (Figure 53). The chlorophyll-a levels in Futch Creek and Smith Creek reached annual maximums in 2007 (Figures 54 and 55). Figure 53- Long term chlorophyll-a data within Pages Creek 43 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Figure 54- Long term chlorophyll-a data within Futch Creek Figure 55- Long term chlorophyll-a data within Smith Creek DISCUSSION Water quality is an important issue in the region due to the fact that there are many economic and recreational opportunities that are supported by the aquatic resources in and around these waterways. One of the greatest threats to water quality in this area is stormwater runoff created by increased impervious surface coverage (Mallin et al., 2000). Polluted stormwater runoff can have many adverse effects on plants, fish, animals and people. Excess nutrients can cause algal blooms while bacteria and other pathogens can wash into swimming areas and create health hazards. New Hanover County has experienced rapid growth and development over the past several decades. In 1990, the population within the County was 120,284. By 2006, the population grew over 50% to 182,591 (U.S. Census Bureau, 2006). Along with this population increase and subsequent stormwater runoff, numerous septic tanks, aging wastewater infrastructure, and other factors potentially impact the water quality within the County’s creeks. With this in mind, it is important to monitor the water quality of these local systems to determine potential impacts to both human health and ecosystem function. 44 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. Typically, water quality degrades as the water warms and oxygen is not as readily dissolved in the water column. Furthermore, longer days allow for increased photosynthetic activity allowing for an increase in phytoplankton blooms. While often more problematic in the summer months, algal blooms are less common in the fall and winter when water temperature decreases. High levels of chlorophyll-a and nutrients along with increases in pH and turbidity may indicate the presence of an algal bloom. Throughout the course of this study, pH values were found to be within acceptable ranges (5.9-9.0) as were turbidity values (with the exception of two individual samples). The lack of elevated pH and turbidity along with generally low chlorophyll-a levels indicate that algal blooms were generally not a problem. The chemical parameter nitrate/nitrite showed a marked difference between the tidal creeks located in proximity to the Intracoastal Waterway and the creeks flowing into the Cape Fear River. The nitrate/nitrite levels were approximately an order of magnitude lower in Pages Creek and Futch Creek, the two creeks draining into the ICW. Further study is required to determine the cause of this sharp difference in nitrate/nitrite levels within these creeks. Dissolved oxygen levels at a number of sites were below the State standard of 5.0 ml/l in SA waters and 4.0 mg/l in C Sw waters. Two sites within Pages Creek, PC-BDDS and PC-BDUS, experienced low dissolved oxygen during five (5) sampling events each. All five sites in Futch Creek experienced low dissolved oxygen during August. Several of the sites within Futch Creek also experienced low dissolved oxygen during the months between June and September when the water temperature was the warmest. Of the creeks draining into the Cape Fear River, Prince Georges Creek demonstrated the lowest dissolved oxygen most likely due to the physical setting surrounding the creek. PG-NC and PG-CH demonstrated low dissolved oxygen six (6) times of the twelve (12) times sampled. This portion of the creek is characterized by a broad shallow bank in a swamp-like setting. It is typical of swamps to contain low levels of dissolved oxygen and higher levels of pH, as observed. Therefore, the low dissolved oxygen observed in Prince Georges Creek, particularly at PG-NC and PG-CH could be regarded as a natural phenomenon. High levels of Enterococci bacteria persisted within all watersheds throughout the study period, with the exception of Lords Creek. Enterococci levels exceeded the State standard in individual sampling sites within Prince Georges Creek, Smith Creek, Pages Creek, Barnards Creek, Futch Creek, and Motts Creek 39%, 50%, 36%, 50%, 8%, and 46% of the time, respectively. Along with Enterococci, fecal coliform bacteria were tested within Pages Creek and Futch Creek. A very high percentage of samples exceeded the single-sample NCDENR Shellfish Sanitation standard of 14 CFU/100ml within these creeks. In fact, 42% of all samples collected within Futch Creek exceeded this standard. Eighty-one percent (81%) of all samples collected within Pages Creek also exceeded this standard. Sources of nutrient and fecal bacteria pollutants can include fertilizers, septic system leachate, leaking sewer mains, wild and domestic animal wastes, and overland runoff (Spivey, 2008). In order to understand and manage fecal bacteria pollution in any body of water, one must first be able to identify the source of the pollution (Kelsey et al. 2004). Previous studies have concluded that increasing the amount of impervious surface coverage increases runoff, stream flow, and the amount of pollutants reaching surface waters (Griffin et al, 1990; Schueler, 1994, Mallin, 2001). Mallin et al. (2000) determined a strong correlation between impervious surface coverage and 45 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. fecal coliform bacteria levels in New Hanover County. Higher impervious surface coverage was found to correlate with a higher geometric mean of fecal coliform bacteria within individual watersheds. New Hanover County has experienced high rates of growth over the past several decades. Along with population increases, the associated development of buildings, roadways, and parking lots within the county has created increased areas of impervious surface coverage. These pollutants include hydrocarbons, bacteria, and nutrients including nitrogen. Major sources of anthropogenic nitrogen are fertilizer application, wastewater disposal and atmospheric deposition (Howarth and Marino, 2006). The conversion of natural landscapes to impervious surfaces removes the natural filtration capacity of the land, thereby facilitating increased concentration of pollutants migrating directly into waterways. A recent assessment of the impervious surface coverage within the watersheds of New Hanover County was performed (Hume, 2008). Impervious surface percentages were determined to be 10.1% in Prince Georges Creek watershed, 11.0% in Futch Creek watershed, 12.6% in Lords Creek watershed, in 13.5% Motts Creek watershed, in 16.9% Barnards Creek watershed, 21.9% in Smith Creek watershed, and 23.3% in Pages Creek watershed. Another potential source of degraded water quality could originate from failing sewage and septic systems. A source tracking study found bacteria originating from humans, ruminants, and canines within six (6) tidal creeks in New Hanover County (Spivey, 2008). In the New Hanover County Water Quality Monitoring Report 2008-2009, it was reported that human borne fecal bacteria was also present within two (2) sites within Pages Creek. The source of this human- borne bacteria may be indicative of either sewer-line problems, septic system failures, or a general persistence in the bacteria itself (Spivey, 2008). New Hanover County and the Cape Fear Public Utility Authority (CFPUA) have investigated the presence of abandoned septic tanks and malfunctioning sewage lift stations in proximity to Pages Creek. These efforts were inconclusive and high levels of Enterococci bacteria and fecal coliform persist within these sites. Failing sewage infrastructure may have contributed to declining water quality within several of the County’s watersheds over recent years. Between June 2009 and June 2010 alone, the CFPUA reported a total of twenty-five (25) sewage spills within New Hanover County. A total of 145,011 gallons were spilled during these events with 132,155 gallons reaching surface waters (Ricks, pers. comm.). A relatively large spill into Smith Creek occurred on June 2, 2010 and accounted for 120,000 gallons of the spill total for the year. As noted above in Table 22, three (3) of the five (5) sites monitored within Smith Creek exceeded the State standard for Enterococci on a regular basis. Thirteen (13) of the twenty-five (25) spills reported between June 2009 and June 2010 were attributed by material (including grease, paper, and baby wipes) clogged in sewer lines. The remaining twelve (12) spills were attributed to pipe failures, power failures, and severe natural conditions. The CFPUA is engaged in a number of sewer infrastructure improvement projects along the Ogden interceptor and other locations to help resolve these issues. In order to minimize future spills, the CPFUA has initiated a public awareness campaign focused on educating its customers on what materials, if flushed into a toilet, could be problematic to the wastewater infrastructure. 46 COASTAL PLANNING & ENGINEERING OF NORTH CAROLINA, INC. LITERATURE CITED Grizzard, T.J., Randall, C.W., Helsel, D.R., and Hartigan, J.P. 1980. Analysis of non-point pollution export from small catchments. Journal of Water Pollution Control Federation, 52: 780-790. Howarth, R.W. and Marino, R. 2006. Nitrogen as the limiting nutrient for eutrophication in coastal marine ecosystems: Evolving views over three decades. Limnology and Oceanography, 51: 364-376. Hume, A. 2008. Determination of Impervious Surface in New Hanover County, North Carolina. Report submitted to New Hanover County. Wilmington, North Carolina. Jeng, J.G., Bradford, H, and Englande, A.J. 2004. "Comparison of E. coli, enterococci, and fecal coliform as indicators for brackish water quality assessment". Water Environmental Research. 76: 245–55. Kelsey, H., Porter, D.E, Scott, G., Neet, M., and White, D. 2004. Using geographic information systems and regression analysis to evaluate relationships between land use and fecal coliform bacterial pollution. Journal of Experimental Marine Biology and Ecology. 298:197-209. Kwak, T.J. and Zedler, J.B. 1997. Food web analysis of southern California coastal wetlands using multiple stable isotopes. Oecologia 110: 262–277. 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