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2006 Ambient Air Quality Report STATE OF NORTH CAROLINA Beverly Eaves Perdue, Governor DEPARTMENT OF ENVIRONMENT AND NATURAL RESOURCES Dee Freeman, Secretary DIVISION OF AIR QUALITY Sheila C. Holman, Director AMBIENT MONITORING SECTION Donald D. Redmond, Jr., Chief PUBLISHED November 2010 ii 2006 Ambient Air Quality Report Ambient Monitoring Section Report # 2010.03 Acknowledgements: Primary Author: Wayne Cornelius Additional Assistance: Lucyna Kozek Vitaly Karpusenko John Holland Public Sources of Data: North Carolina Division of Air Quality http://daq.state.nc.us/ Forsyth County Environmental Affairs Department http://www.co.forsyth.nc.us/EnvAffairs/weathereport.htm EPA/AQS Air Quality Subsystem http://www.epa.gov/airsweb National Atmospheric Deposition Program http://nadp.sws.uiuc.edu Published: November 2010 Not copyrighted. iii Preface This report is issued by the Division of Air Quality of the Department of Environment and Natural Resources to inform the public about air pollution levels throughout the state of North Carolina. It describes the sources and effects of the following pollutants for which the U.S. Environmental Protection Agency and the State of North Carolina have established ambient air quality standards: Particulate Matter Sulfur Dioxide Ozone Carbon Monoxide Nitrogen Dioxide Lead The report begins with a brief discussion of the ambient air monitoring program, including a description of the monitoring network. It presents detailed results of monitoring that was conducted in 2006 to measure the outdoor concentrations. The data are presented graphically and as statistical summaries, including comparisons to the ambient air quality standards. The report discusses the recorded data, and the seasonal variability of some pollutants. Data and areas exceeding the ambient air quality standards are identified. Factors that have contributed to those exceedances are also described. Acid rain data summaries from the National Atmospheric Deposition Program/National Trends Network for North Carolina also are included for 2006. Current air pollution information is available to the public 24 hours a day through the use of the air quality index telephone numbers listed below: Statewide toll-free 888-AIR-WISE (for Asheville, Charlotte, Fayetteville, Greenville, Hickory, Raleigh, Rocky Mount, Wilmington and Winston-Salem metro areas) Charlotte area 704-333-SMOG (for Mecklenburg County only) In 2002, the air monitoring program deployed a network of fine particle speciation monitors. This report provides data summaries from these monitors for 2006. Also in 2002, the Division of Air Quality established a small network of Urban Air Toxics monitors. It supplements a new national toxics database, and some key toxics pollutants are summarized for 2006 in this report. iv The report also contains graphical summaries of long-term annual trends for the criteria pollutants and acid rain data, highlighting successful efforts at pollution control and suggesting where future priorities should be placed. Additional copies of this report and previous annual reports are available on the Division of Air Quality‟s website http://daq.state.nc.us/monitor/reports/ or by writing to: Division of Air Quality 1641 Mail Service Center Raleigh, North Carolina 27699-1641 Comments regarding this report or suggestions for improving future reports are welcomed. Comments may be sent to Dr. Wayne L. Cornelius, at the above address. Sheila C. Holman, Director Division of Air Quality v Executive Summary In 2006, the North Carolina Division of Air Quality (DAQ), the three local program agencies and one tribal agency (listed in Appendix A) collected 305,161 air quality samples. These samples included measurements of the U.S. Environmental Protection Agency‟s (EPA) criteria air pollutants: particulate matter, carbon monoxide, ozone, sulfur dioxide, nitrogen dioxide and lead. This report discusses each pollutant and presents summary tables, maps, charts and explanations of the data. The report also includes data from weekly acid rain samples collected by the National Atmospheric Deposition Program (NADP) at seven North Carolina sites and one Tennessee site very close to the North Carolina border. It discusses acid rain and presents summary tables, maps, charts and explanations of the data. This report provides data summaries from a network of fine particle speciation monitors for 2006. The DAQ and two federal agencies deployed these monitors in 2002 to characterize more fully fine particulate matter by composition. This report presents a map and summary tables of the major speciation categories for 2006. Also in 2002, the Division of Air Quality established a small network of Urban Air Toxics monitors. It supplements a new national toxics database, and some key toxics pollutants are summarized for 2006 in this report. This report presents a map and summary tables of formaldehyde and five important volatile organic compounds for 2006. The report also contains graphical summaries of long-term annual trends for the criteria pollutants and acid rain data, highlighting successful efforts at pollution control and suggesting where future priorities should be placed. Three different types of particulate matter were sampled in North Carolina during 2006. Total Suspended Particulate (TSP), or particles having an aerodynamic diameter of 100 micrometers or less, is regulated by North Carolina standards. Particulate matter (PM10), with a mean aerodynamic diameter less than or equal to a nominal 10 micrometers (0.00004 inches), is regulated by both EPA and N.C. standards. Fine particulate matter (PM2.5), with a mean aerodynamic diameter less than or equal to a nominal 2.5 micrometers (0.00001 inches), has been regulated by EPA and NC since 1999. In 2006, TSP was sampled at seven sites, yielding 361 daily samples. There were no exceedances of the state TSP ambient air quality standard for 24-hour samples (150 g/m3) observed in 2006. PM10 was sampled at 15 sites, yielding 1,717 daily samples. There were no exceedances of the National Ambient Air Quality Standards for PM10 (150 g/m3 for 24-hour samples and 50 g/m3 for the annual arithmetic mean). vi PM2.5 was sampled at 35 sites yielding 5,176 daily samples. There were 17 exceedances of the ambient air quality standards for PM2.5 (35 g/m3 for 24-hour samples). Two of the 35 sites exceeded the annual arithmetic mean standard of 15 g/m3. Carbon monoxide (CO), largely results from fuel combustion. The most likely areas to have excessive CO concentrations are larger cities where there are more cars and congested streets. CO was sampled at five sites, yielding 28,259 valid hourly averages. The National Ambient Air Quality Standards for CO are 35 ppm for the maximum one-hour average and 9 ppm for the maximum eight-hour average. There were no exceedances of the standards. The highest one-hour concentration of 4.0 ppm was observed at the ABC Board in Cumberland County. The highest eight-hour concentration of 3.0 ppm was observed at the ABC Board in Cumberland County. The mean one-hour average has been decreasing by about 13 percent per year and the mean eight-hour average has been decreasing by about 15 percent per year. The combined effects of newer cars in the vehicle fleet, traffic control strategies, and the Inspection and Maintenance program in Cumberland, Durham, Orange, Wake, Forsyth, Guilford, Cabarrus, Gaston, Mecklenburg, and Union Counties have helped reduce the number and intensity of CO exceedances from previous years. Ozone (O3) forms in the lower atmosphere when hydrocarbons (or volatile organic compounds) and nitrogen oxides chemically react in the presence of sunlight and high temperatures. The main emphasis in control of ozone has been to limit hydrocarbon and nitrogen oxide emissions. O3 was sampled at 42 sites, yielding 205,680 valid hourly averages. The National Ambient Air Quality Standard for O3 in 2006 was 0.08 ppm for the maximum eight-hour average and 0.12 ppm for the maximum one-hour average. In 2006, there were no exceedances of the one-hour standard. Four exceedances occurred in North Carolina in 2005, and no exceedances occurred in 2004. Mecklenburg, Rowan and Wake Counties met or exceeded the criteria for attainment of the one-hour ozone standard with three, one and zero exceedances respectively over a three-year period. Mecklenburg County was redesignated as in attainment for ozone in July 1995. Hydrocarbon and NOx control strategies continue to be used there to help reduce ozone concentrations. In 2006, the 8-hour standard was exceeded 48 times, on 20 different days, with one county having eight exceedances at individual sites. The site at 29 N @ Mecklenburg Cab Co, Charlotte in Mecklenburg County had the highest number, eight. Sulfur dioxide (SO2) is mainly produced by combustion of fossil fuels containing sulfur compounds and the manufacture of sulfuric acid. SO2 was sampled at eight sites, yielding 49,788 valid hourly averages. There were no exceedances of the National Ambient Air Quality Standards (365 g/m3 or 0.14 ppm for a 24-hour average, 1300 g/m3 or 0.50 ppm for a three-hour average, 80 g/m3 or 0.03 ppm for the annual arithmetic mean) at network monitoring sites. vii Nitrogen oxides (NOx) are produced primarily from the burning of fossil fuels such as coal, oil and gasoline, due to the oxidation of atmospheric nitrogen and nitrogen compounds in the fuel. The primary combustion product is NO, which reacts with hydrocarbons, ozone and other atmospheric compounds to form NO2. NOx compounds play an important role in the formation of ozone. Reactive nitrogen species (NOy) were monitored in Charlotte and Winston-Salem to gather data for the development of control strategies for ozone non-attainment areas. The criteria pollutant NO2 was sampled at two sites, yielding 14,180 valid hourly averages. There were no exceedances of the National Ambient Air Quality Standard (0.053 ppm for the annual arithmetic mean). The mean one-hour average concentration has been decreasing by about 10 percent per year. Lead (Pb) emissions result from coal combustion and the sandblasting of highway bridges, overpasses, and water tanks. In the past, the combustion of gasoline containing tetraethyl lead as an additive was a major source. Lead was not sampled in 2006 using a Federal Reference Method. There have been no recent exceedances of the ambient air quality standard for lead (1.5 g/m3 for a quarterly arithmetic mean). From 1979 through 1999, mean lead concentrations have decreased by 92 percent. The steady decline in the use of leaded gasoline is primarily responsible for this trend. Acid Rain is produced when nitrate and sulfate ions from motor vehicles, combustion and industrial sources reach the upper atmosphere, react with moisture in the air, and are deposited as acid precipitation. Monitoring of pH and other ion concentrations in precipitation will help to identify trends and demonstrate the results of efforts to reduce emissions from mobile and industrial sources. The annual mean pH in 2006 ranged from 4.57 (Rowan County) to 4.90 (Sampson County). Speciated particulate samples were collected at 12 sites by the DAQ, two sites by the National Park Service and one site by the U.S. Forest Service. Categorizing these as nitrates, sulfates, ammonium, organic carbon, elemental carbon, crustal material, and “other” constitutents (liquid water, trace elements, etc.), there were 5,559 quantifiable concentrations 2006. By category, the highest concentrations of speciated particulate samples in 2006 were: sulfate 17.73 μg/m3; organic carbon 16.10 μg/m3; crustal component 6.01 μg/m3; nitrate 5.71 μg/m3; ammonium 4.96 μg/m3; elemental carbon 3.68 μg/m3; and other 70.12 μg/m3. Although there was no sampling for lead using a criteria pollutant method, the speciated particulate monitoring network provided 888 samples of PM2.5-lead in 2006; 854 of these sample concentrations (96 percent) were less than 0.01 μg/m3. Twelve samples exceeded 0.014 μg/m3. viii Urban Air Toxics sampling in 2006 occurred at seven sites, six urban and one rural. This effort contributes to the U.S. EPA‟s Air Toxics Monitoring Strategy by providing data to help assess health risks. The median concentrations of formaldehyde were 1.28-2.21 ppb at the urban sites and 1.50 ppb at the rural site. Median benzene concentrations were 0.27 to 0.37 ppb at the urban sites and 0.24 ppb at the rural site. Median toluene concentrations were 0.24 to 0.81 ppb at the urban sites and 0.17 ppb at the rural site. Median ethylbenzene concentrations were 0.05 to 0.14 ppb at the urban sites and 0.05 ppb at the rural site. Median m/p-xylene concentrations were 0.09 to 0.46 ppb at the urban sites and 0.05 ppb at the rural site. Median o-xylene concentrations were 0.05 to 0.14 ppb at the urban sites and 0.05 at the rural site. Median 1, 3-butadiene concentrations were 0.05 ppb at the urban sites and at the rural site. Ambient Trends: Annual average statewide concentrations of PM10 decreased by 29 percent from 1989 to 2006. Annual average statewide concentrations of CO (as 8-hour averages) have decreased by 49 percent from 1995 to 2006. Annual average highest 8-hour ozone concentrations decreased by 12 percent from 1990 to 2006. Annual average highest 3-hour sulfur dioxide concentrations decreased by 63 percent from 1989 to 2006, and annual average of annual means decreased by 58 percent in the same time period. Annual average nitrogen dioxide concentrations remained constant from 1989 to 2006 in Forsyth County and Mecklenburg County, the only locations where this pollutant is monitored at present. Acid Rain Trends: Annual average pH in rain increased about 4 percent from 1991 to 2006. Annual average ammonium concentrations increased about 29 percent from 1991 to 2006, but this was dominated by very significant increases in Sampson County associated with concentrated livestock animal production. Annual average nitrate concentrations in rain decreased about 21 percent from 1991 to 2006. Annual average sulfate concentrations in rain decreased about 19 percent from 1991 to 2006. ix CONTENTS 1 Introduction ................................................................................................................................ 1 2 Descriptions of Criteria Pollutants .............................................................................................. 2 2.1 Particulate Matter ..................................................................................................................... 2 2.1.1 Sources ............................................................................................................................... 2 2.1.2 Effects ................................................................................................................................ 2 2.2 Carbon Monoxide .................................................................................................................... 3 2.2.1 Sources ............................................................................................................................... 3 2.1.2 Effects ................................................................................................................................ 3 2.3 Ozone ...................................................................................................................................... 3 2.3.1 Sources ............................................................................................................................... 4 2.3.2 Effects ................................................................................................................................ 4 2.4 Sulfur Dioxide ......................................................................................................................... 4 2.4.1 Sources ............................................................................................................................... 4 2.4.2 Effects ................................................................................................................................ 4 2.5 Nitrogen Oxides ...................................................................................................................... 5 2.5.1 Sources ............................................................................................................................... 5 2.5.2 Effects ................................................................................................................................ 5 2.6 Lead........................................................................................................................................ 5 2.6.1 Sources ............................................................................................................................... 5 2.6.2 Effects ................................................................................................................................ 6 3 Standards .................................................................................................................................. 7 4 Ambient Air Quality Monitoring Program ............................................................................... 9 5 Pollutant Monitoring Results .................................................................................................. 16 5.1 Total Suspended Particulates ................................................................................................ 16 5.2 PM10 ..................................................................................................................................... 18 5.3 Fine Particulate Matter, (PM2.5) ............................................................................................ 20 5.4 Carbon Monoxide ................................................................................................................. 27 5.5 Ozone .................................................................................................................................. 30 5.6 Sulfur Dioxide ...................................................................................................................... 39 5.7 Nitrogen Dioxide ................................................................................................................. 43 5.8 Lead..................................................................................................................................... 44 5.8.1 Special Studies .................................................................................................................... 44 6 Air Quality Index .................................................................................................................. 45 7 Acid Rain .............................................................................................................................. 53 7.1 Sources .............................................................................................................................. 54 7.2 Effects ............................................................................................................................... 54 7.3 Monitoring ............................................................................................................................ 54 8. Fine Particle Speciation ........................................................................................................ 58 8.1 Description of Pollutants...................................................................................................... 58 8.1.1 Nitrate ............................................................................................................................... 58 8.1.2 Sulfate ............................................................................................................................... 58 8.1.3 Ammonium ....................................................................................................................... 58 8.1.4 Organic Carbon ................................................................................................................. 58 8.1.5 Elemental Carbon.............................................................................................................. 58 x 8.1.6 Crustal Component (Fine Dust) ........................................................................................ 59 8.1.7 “Other” Speciated Components. ........................................................................................ 59 8.2 Sources .............................................................................................................................. 59 8.3 Effects ............................................................................................................................... 60 8.4 Monitoring ........................................................................................................................ 60 9. Urban Air Toxics ..................................................................................................................... 70 9.1 Sources .............................................................................................................................. 70 9.2 Effects ............................................................................................................................... 70 9.3 Formaldehyde ....................................................................................................................... 71 9.3.1 Sources .............................................................................................................................. 71 9.3.2 Effects ............................................................................................................................... 71 9.4 Benzene ................................................................................................................................ 71 9.4.1 Sources .............................................................................................................................. 71 9.4.2 Effects ............................................................................................................................... 71 9.5 Toluene ................................................................................................................................ 72 9.5.1 Sources .............................................................................................................................. 72 9.5.2 Effects ............................................................................................................................... 72 9.6 Ethylbenzene .......................................................................................................................... 72 9.6.1 Sources .............................................................................................................................. 72 9.6.2 Effects ............................................................................................................................... 73 9.7 Xylene ................................................................................................................................... 73 9.7.1 Sources .............................................................................................................................. 73 9.7.2 Effects ............................................................................................................................... 73 9.8 1,3 Butadiene ......................................................................................................................... 73 9.8.1 Sources .............................................................................................................................. 73 9.8.2 Effects ............................................................................................................................... 74 9.9 Monitoring 2006 ................................................................................................................... 74 10 Statewide Trends .................................................................................................................. 81 10.1 Particulate Matter ................................................................................................................. 81 10.2 Carbon Monoxide ................................................................................................................ 81 10.3 Ozone .................................................................................................................................. 81 10.4 Sulfur Dioxide ..................................................................................................................... 81 10.5 Nitrogen Dioxide ................................................................................................................. 82 10.6 pH ........................................................................................................................................ 82 10.7 Ammonium Ion .................................................................................................................... 82 10.8 Nitrate Ion ............................................................................................................................ 82 10.9 Sulfate Ion ............................................................................................................................ 83 Appendix A. Air Pollution Monitoring Agencies ......................................................................... 90 Appendix B. Exceptional Events .................................................................................................. 93 Appendix C. Box-And-Whisker Plots .......................................................................................... 94 Appendix D. Nonattainment and North Carolina ......................................................................... 95 xi List of Tables Table 3.1 National and North Carolina Ambient Air Quality Standards ........................................ 8 Table 4.1 Ambient Air Monitoring Sites Operated in North Carolina, 2006 ............................... 11 Table 5.1 Total Suspended Particulates in Micrograms Per Cubic Meter for 2006 ..................... 17 Table 5.2 PM10 in Micrograms Per Cubic Meter for 2006 ........................................................... 19 Table 5.3 PM2.5 in Micrograms Per Cubic Meter for 2006........................................................... 22 Table 5.4 Carbon Monoxide in Parts Per Million for 2006 .......................................................... 28 Table 5.5 One-Hour Ozone in Parts Per Million for 2006 ........................................................... 31 Table 5.6 Eight-Hour Ozone in Parts Per Million for 2006 .......................................................... 35 Table 5.7 Sulfur Dioxide in Parts Per Million from All Sites for 2004-2006 .............................. 40 Table 5.8 Nitrogen Dioxide in Parts Per Million for 2006 ........................................................... 43 Table 6.1 Air Quality Index Category Days in the Major Metropolitan Statistical Areas, 2006 . 47 Table 7.1 pH, Conductivity in Microsiemans per Centimeter and Precipitation in Inches from the National Atmospheric Deposition Program for 2006 ........................................................... 56 Table 7.2 Ion Concentrations in Milligrams per Liter (Precipitation-weighted Annual Means) from the National Atmospheric Deposition Program Data for 2006 .................................... 57 Table 8.1 Fine Particles Speciation Sites Operated in North Carolina in 2006 ............................ 62 Table 8.2 Nitrate PM2.5- Micrograms/Cubic Meter (LC) for 2006 ............................................... 63 Table 8.3 Sulfate PM2.5- Micrograms/Cubic Meter (LC) for 2006 .............................................. 64 Table 8.4 Ammonium Ion PM2.5- Micrograms/Cubic Meter (LC) for 2006 ................................ 65 Table 8.5 Organic Carbon CSN PM2.5- Micrograms/Cubic Meter (LC) for 2006 ....................... 66 Table 8.6 Elemental Carbon CSN PM2.5- Micrograms/Cubic Meter (LC) for 2006 .................... 66 Table 8.7 Crustal Component PM2.5- Micrograms/Cubic Meter (LC) for 2006........................... 67 Table 8.8 Lead PM2.5- Micrograms/Cubic Meter (LC) for 2006 .................................................. 68 Table 8.9 “Other” Component PM2.5- Micrograms/Cubic Meter (LC) for 2006 ......................... 69 Table 9.1 Formaldehyde - Parts per billion for 2006 .................................................................... 76 Table 9.2 Benzene - Parts per billion for 2006 ............................................................................. 77 Table 9.3 Toluene - Parts per billion for 2006 .............................................................................. 77 Table 9.4 Ethylbenzene - Parts per billion for 2006 ..................................................................... 78 Table 9.5 m/p-Xylene - Parts per billion for 2006 ........................................................................ 79 Table 9.6 o-Xylene -Parts per billion for 2006 ............................................................................. 79 Table 9.7 1,3-Butadiene ................................................................................................................ 80 xii List of Figures Figure 4.1 Monitoring Sites Active in 2006 ................................................................................. 10 Figure 5.1 Location of PM10 Monitoring Sites ............................................................................. 18 Figure 5.2 PM10: Second Highest 24-Hour Averages, 2006 ........................................................ 20 Figure 5.3 PM10: Maximum Annual Arithmetic Means, 2006 .................................................... 20 Figure 5.4 Location of PM2.5 Monitoring Sites ............................................................................ 22 Figure 5.5 PM2.5: 98th percentile, 2006 ........................................................................................ 25 Figure 5.6 PM2.5: Annual Arithmetic Means, 2006 ..................................................................... 25 Figure 5.7 PM2.5: Design Values by County, 2004-2006 ............................................................ 26 Figure 5.8 Location of Carbon Monoxide Monitoring Sites ........................................................ 28 Figure 5.9 Carbon Monoxide: Second Highest 1-Hour Concentration, 2006 .............................. 29 Figure 5.10 Carbon Monoxide: Second Highest Non-overlapping 8-Hour Concentration, 2006 29 Figure 5.11 Location of Ozone Monitoring Sites ......................................................................... 31 Figure 5.12 Ozone: Second Highest Annual 1-Hour Average, 2006 ........................................... 38 Figure 5.13 Ozone: Mean Annual Fourth Highest 8-Hour Average, 2004-2006 ........................ 38 Figure 5.14 Locations of Sulfur Dioxide Monitoring Sites in 2004, 2005 and 2006 ................... 40 Figure 5.15 Sulfur Dioxide: Second Highest 3-Hour Averages in the Most recent Year of Data from 2004, 2005 and 2006 .................................................................................................... 42 Figure 5.16 Sulfur Dioxide: Second Highest 24-Hour Averages in the Most Recent Year of Data from 2004, 2005 or 2006 ...................................................................................................... 42 Figure 5.17 Location of Nitrogen Dioxide Monitoring Sites ...................................................... 43 Figure 6.1 Daily Air Quality Index Values for Asheville ............................................................ 48 Figure 6.2 Daily Air Quality Index Summary for Asheville ........................................................ 48 Figure 6.3 Daily Air Quality Index Values for Charlotte-Gastonia .............................................. 49 Figure 6.4 Daily Air Quality Index Summary for Charlotte-Gastonia ......................................... 49 Figure 6.5 Daily Air Quality Index Values for Fayetteville ......................................................... 50 Figure 6.6 Daily Air Quality Index Summary for Fayetteville ..................................................... 50 Figure 6.7 Daily Air Quality Index Values Greensboro-Winston-Salem-High Point .................. 51 Figure 6.8 Daily Air Quality Index Summary Greensboro-Winston-Salem-High Point .............. 51 Figure 6.9 Daily Air Quality Index Values for Raleigh-Durham- Chapel Hill ............................ 52 Figure 6.10 Daily Air Quality Index Summary for Raleigh-Durham-Chapel Hill ....................... 52 Figure 6.11 Daily Air Quality Index Values for Wilmington ....................................................... 53 Figure 6.12 Daily Air Quality Index Summary for Wilmington .................................................. 53 Figure 7.1 Annual Mean pH Values at North Carolina NADP Sites, 2006.................................. 55 Figure 8.1 Location of Nitrate, Sulfate, Ammonium, Organic Carbon, Elemental Carbon, Crustal component, "Other" component, Monitoring Sites 2006 ...................................................... 62 Figure 9.1 Location Urban Air Toxics Monitoring Sites 2006 ..................................................... 76 Figure 10.1 Distribution of Statewide Second-Maximum 24-Hour PM10 Concentrations, 1989- 2006, and Smoothed Regression Trend Line ....................................................................... 83 xiii Figure 10.2 Distribution of Statewide Second-Maximum 8-Hour Carbon Monoxide Concentrations, 1994-2006, and Smoothed Regression Trend Line ................................... 84 Figure 10.3 Distribution of Statewide Fourth-Maximum 8-Hour Ozone Concentrations, 1990- 2006, and Smoothed Regression Trend Line ....................................................................... 84 Figure 10.4 Number of Days with Exceedances of 8-Hour Ozone Averages of 0.085 ppm or Greater, 1990-2006 ............................................................................................................ 85 Figure 10.5 Distribution of Statewide Second-Maximum 3-Hour Sulfur Dioxide Concentrations, 1989- 2006, and Smoothed Regression Trend Line ............................................................ 85 Figure 10.6 Distribution of Statewide Second- Maximum 24-Hour Sulfur Dioxide Concentrations, 1989- 2006, and Smoothed Regression Trend Line ................................. 86 Figure 10.7 Distributions of Forsyth and Mecklenburg County Annual Mean Nitrogen Dioxide Concentrations, 1989- 2006, and Smoothed Regression Trend Line .................................. 86 Figure 10.8 Distribution of Statewide Annual Mean pH, 1991- 2006.......................................... 87 Figure 10.9 Distribution of Statewide Annual Mean Ammonium Ion Concentrations, 1991- 2006 .......................................................................................................................... 87 Figure 10.10 Distribution of Statewide Annual Mean Nitrate Ion Concentrations, 1991- 2006, and Smoothed Regression Trend Line ................................................................................. 88 Figure 10.11 Distribution of Statewide Annual Mean Sulfate Ion Concentrations, 1991- 2006, and Smoothed Regression Trend Line .................................................................................. 88 1 1. Introduction This annual report summarizes the ambient air monitoring performed in calendar year 2006 by the North Carolina Division of Air Quality (DAQ), three local air pollution agencies and one tribal agency, which are more fully described in Appendix A. These agencies collected 305,161 air quality samples of the U.S. Environmental Protection Agency‟s (EPA) criteria pollutants (particulate matter, carbon monoxide, ozone, sulfur dioxide, nitrogen dioxide and lead), which are discussed in this report. Chapter 2 describes the criteria pollutants and discusses their sources and effects on human health, plants and animals. Chapter 3 outlines the standards applied to criteria pollutant concentrations established by the EPA and the state of North Carolina to protect human health (primary standards) and plants, animals, and property (secondary standards). Chapter 4 describes the ambient monitoring program conducted by DAQ and three local program agencies. Chapter 5 gives detailed monitoring results for each pollutant, with a map of the monitor sites, a table of the monitor summary statistics relevant to the standards, one or more maps summarizing the important statistics for each county with monitors, and additional summaries as appropriate to each pollutant. Chapter 6 describes the EPA Air Quality Index for the criteria pollutants and charts index measurements for five Metropolitan Statistical Areas of North Carolina. Chapter 7 presents sources, effects and monitoring of acid rain data conducted in North Carolina by the National Atmospheric Deposition Program and National Trends Network (NADP). It also includes a map of the calendar year mean pH level and site statistics for the calendar year in two tables. Chapter 8 describes a small network of fine particulate speciation compounds that DAQ initiated in 2002. The chapter contains annual summaries of seven main components of fine particles. We also report summary of lead here (instead of chapter 5). Chapter 9 describes the Urban Air Toxics monitoring program in North Carolina. The DAQ and local air pollution agencies sampled volatile organic compounds at seven sites. This chapter contains annual summaries for five important toxic pollutants. Chapter 10 provides a statewide summary of trends for the criteria pollutants from 1989 and 1991 (1994 for CO and 1990 for O3) through 2006. 2 2 Descriptions of Criteria Pollutants 2.1 Particulate Matter Atmospheric particulate matter is defined as any airborne material, except uncombined water (liquid, mist, steam, etc.), that exists in a finely divided form as a liquid or solid at standard temperature (25° C) and pressure (760 mm mercury) and has an aerodynamic diameter of less than 100 micrometers (m). In the period covered by this report, three sizes of particulate matter were monitored, total suspended particulate (TSP), PM10 and PM2.5. TSP is any particulate matter measured by the method described in EPA regulations 40 CFR 50 App. B (United States Environmental Protection Agency [US EPA] 1993, p. 715-728) and is generally considered to be particles having an aerodynamic diameter of 40 m or less (Watson and Chow 2001), although particles up to about 100 m are sometimes captured by samplers. (The probability of inhalation for 100 m particles is about 50 percent and increases with decreasing particle size [Maynard and Jensen 2001].) PM10 is particulate matter with an aerodynamic diameter less than or equal to 10 m as measured according to EPA regulations 40 CFR 50 App. J (US EPA 1993, p. 769-773). TSP measurements have been made in North Carolina since the early 1960s, and PM10 has been sampled locally in Charlotte since 1985 and statewide since 1986 (North Carolina Department of Environment, Health, and Natural Resources 1991a). The PM2.5 standard was adopted by North Carolina on April 1, 1999. On May 14, 1999, the U.S. Court of Appeals ruled the setting of the standard by EPA was an unconstitutional use of authority and could be vacated. The Supreme Court later upheld the new standard. EPA continues to require monitoring for PM2.5. 2.1.1 Sources Particulates are emitted by many human activities, such as fuel combustion, motor vehicle operation, industrial processes, grass mowing, agricultural tilling and open burning. Natural sources include windblown dust, forest fires, volcanic eruptions, and plant pollen. Particles emitted directly from a source may be either fine (less than 2.5 m) or larger (2.5 - 60 m), but particles photo-chemically formed in the atmosphere will usually be fine. Generally, larger particles have very slow settling velocities and are characterized as suspended particulate matter. Typically, fine particles originate from condensation of materials produced during combustion or atmospheric reactions. 2.1.2 Effects Particulate matter can cause health problems affecting the breathing system, including aggravation of existing lung and heart disease, limitation of lung clearance, changes in form and structure of organs, and development of cancer. Individuals most 3 sensitive to the effects of particulate matter include those with chronic obstructive lung or heart disease, those suffering from the flu, asthmatics, the elderly, children, and mouth breathers. Health effects from inhaled particles are influenced by the depth of penetration of the particles into the respiratory system, the amount of particles deposited in the respiratory system, and by the biological reaction to the deposited particles. The risks of adverse health effects are greater when particles enter the tracheobronchial and alveolar portions of the respiratory system. Small particles can penetrate into these deeper regions of the respiratory system. Healthy respiratory systems can trap particles larger than 10 micrometers more efficiently before they move deeply into the system and can more effectively remove the particles that are not trapped before deep movement. Particulate matter also can interfere with plant photosynthesis, by forming a film on leaves reducing exposure to sunlight. Particles also can cause soiling and degradation of property, which can be costly to clean and maintain. Suspended particles can absorb and scatter light, causing reduction of visibility. This is a national concern, especially in areas such as national parks, historic sites and scenic attractions visited by sightseers. 2.2 Carbon Monoxide Carbon monoxide (CO) is the most commonly occurring air pollutant. CO is a colorless and poisonous gas produced by incomplete burning of carbon-containing fuel. 2.2.1 Sources Most atmospheric CO is produced by incomplete combustion of fuels used for vehicles, space heating, industrial processes and solid waste incineration. Transportation accounts for the majority of CO emissions. Boilers and other fuel burning heating systems are also significant sources. 2.1.2 Effects Breathing carbon monoxide affects the oxygen-carrying capacity of the blood. Hemoglobin in the blood binds with CO more readily than with oxygen, starving the body of vital oxygen. Individuals with anemia, lung and heart diseases are particularly sensitive to CO effects. Low concentrations affect mental function, vision and alertness. High concentrations can cause fatigue, reduced work capacity and may adversely affect fetal development. Chronic exposure to CO at concentrations as low as 70 ppm (80 mg/m3) can cause cardiac damage. Other health effects associated with exposure to CO include central nervous system effects and pulmonary function difficulties. Ambient CO apparently does not adversely affect vegetation or materials. 2.3 Ozone Ozone is a clear gas that forms in the troposphere (lower atmosphere) by chemical reactions involving hydrocarbons (or volatile organic compounds) and nitrogen oxides in the presence of sunlight and high temperatures. Even low concentrations of 4 tropospheric ozone are harmful to people, animals, vegetation and materials. Ozone is the most widespread and serious criteria air pollutant in North Carolina. Ozone in the upper atmosphere (stratosphere) shields the earth from harmful effects of ultraviolet solar radiation. Stratospheric ozone can be damaged by the emission of chlorofluoro hydrocarbons (CFCs) such as Freon. 2.3.1 Sources Ozone (O3) is the major component of a complex mixture of compounds known as photochemical oxidants. Ozone is not usually emitted directly into the atmosphere, but is formed by a series of complex reactions involving hydrocarbons, nitrogen oxides and sunlight. Ozone concentrations are higher during the daytime in late spring, summer and early autumn when the temperature is above 60º F and the sunlight is more intense. Two natural sources of upper atmosphere ozone are solar radiation and lightning during thunderstorms. These are not significant sources of tropospheric (ground level) ozone. 2.3.2 Effects Ozone is a pulmonary irritant, affecting the respiratory mucous membranes, as well as other lung tissues and respiratory functions. Ozone has been shown to impair normal function of the lung causing shallow, rapid breathing and a decrease in pulmonary function. Other symptoms of exposure include chest tightness, coughing and wheezing. People with asthma, bronchitis or emphysema probably will experience breathing difficulty when exposed to short-term concentrations between 0.15 and 0.25 ppm. Continued or repeated long-term exposure may result in permanent lung structure damage. Ozone damages vegetation by injuring leaves. Ozone also accelerates material aging by cracking rubber, fading dyes and eroding paint. 2.4 Sulfur Dioxide Sulfur dioxide (SO2) is a colorless, corrosive, harmful gas with a pungent odor. Smaller concentrations of sulfur trioxide and other sulfate compounds are also found in SO2 emissions. Sulfur oxides contribute to the formation of acid rain and the formation of particles that reduce visibility. 2.4.1 Sources The main sources of SO2 are combustion of fossil fuels containing sulfur compounds and the manufacture of sulfuric acid. Other sources include refining of petroleum and smelting of ores that contain sulfur. 2.4.2 Effects The most obvious health effect of sulfur dioxide is irritation and inflammation of body tissues brought in contact with the gas. Sulfur dioxide can increase the severity of existing respiratory diseases such as asthma, bronchitis, and emphysema. Sulfuric acid and fine particulate sulfates, which are formed from sulfur dioxide, also may cause significant health problems. Sulfur dioxide causes injury to many plants. A bleached 5 appearance between the veins and margins on leaves indicates damage from SO2 exposure. Commercially important plants sensitive to SO2 include cotton, sweet potatoes, cucumber, alfalfa, tulips, apple trees, and several species of pine trees. 2.5 Nitrogen Oxides Several gaseous oxides of nitrogen are normally found in the atmosphere, including nitrous oxide (N2O), nitric oxide (NO) and nitrogen dioxide (NO2). Nitrous oxide is a stable gas with anesthetic characteristics and typical ambient concentrations well below the threshold concentration for a biological effect. Nitric oxide is a colorless gas with ambient concentrations generally low enough to have no significant biological effect. Nitrogen dioxide is reddish-brown but is not usually visible at typical ambient concentrations. 2.5.1 Sources The most significant nitrogen oxide emissions result from the burning of fossil fuels such as coal, oil and gasoline, due to the oxidation of atmospheric nitrogen and nitrogen compounds in the fuel. The primary combustion product is NO, which reacts to form NO2. 2.5.2 Effects At typical concentrations, nitrogen dioxide has significant health effects as a pulmonary irritant, especially upon asthmatics and children. In North Carolina, a much greater health concern is the formation of ozone, which is promoted by the presence of NO2 and other nitrogen oxides. Some types of vegetation are very sensitive to NO2, including oats, alfalfa, tobacco, peas and carrots. Chronic exposure causes chlorosis (yellowing) and acute exposure usually causes irregularly shaped lesions on the leaves. Nitric oxide and nitrogen dioxide do not directly damage materials. However, NO2 can react with moisture in the air to produce nitric acid, which corrodes metal surfaces and contributes to acid rain. High concentrations of NO2 may reduce visibility. Much of the brownish coloration sometimes observed in polluted air in winter months may be due to NO2. 2.6 Lead Lead is a toxic heavy metal element occurring in the atmosphere as small particles. 2.6.1 Sources The major source of atmospheric lead used to be the combustion of gasoline containing the additive tetraethyl lead as an anti-knock agent. However, the availability of leaded fuel has declined, and the concentration of lead in such fuel has decreased, minimizing gasoline as a source. Significant remaining sources include coal combustion (lead exists in very small quantities as an impurity in coal) and sandblasting of highway structures and water tanks. Lead also is used in some batteries, paints, insecticides, newspaper inks and piston engine aircraft gasoline. 6 2.6.2 Effects Lead (Pb) persists and accumulates in the environment and the human body. It may be inhaled, ingested, and eventually absorbed into the bloodstream and distributed to all body tissues. Exposure to low concentrations interferes with blood production and specific enzyme systems. It is believed to cause kidney and nerve cell damage, and severe lead poisoning is known to cause brain damage in children. 7 3 Standards Ambient air quality status is determined by measuring pollutant concentrations in outdoor air and comparing the measured concentrations to corresponding standards. The US EPA (Environmental Protection Agency) defines the ambient air as “that portion of the atmosphere, external to buildings, to which the general public has access.” Ambient air quality standards are classified as primary and secondary. Primary standards are those established to protect public health. Secondary standards are those established to protect the public welfare from adverse pollution effects on soils, water, crops, vegetation, man-made materials, animals, wildlife, weather, visibility, climate, property, transportation, economy, and personal comfort and well-being. The scientific criteria upon which the standards are based are reviewed periodically by the EPA, which may reestablish or change the standards according to its findings. A pollutant measurement that is greater than the ambient air quality standard for a specific averaging time is called an exceedance. The national primary, secondary and North Carolina ambient air quality standards that were in effect during 2006 are summarized in Table 3.1. 8 Table 3.1 National and North Carolina Ambient Air Quality Standards For new or anticipated new standards, References in the Code of Federal Regulations are given. For standards expressed in parts per million, an equivalent mass per unit volume is also shown. Pollutant/ Ambient Measurement/ (Reference) Averaging Period Type of Summary Primary National (Health Related) Standard Secondary National (Welfare Related) Standard North Carolina Standard TSP 24 hour average 1 year geometric mean (1) (1) 75 μg/m3 1 day 2nd maximum (1) (1) 150 μg/m3 PM-2.5 24 hour average (40CFR50, App. N) 1 year average2 arithmetic mean 15 μg/m3 (6) 15 μg/m3 (6) 15 μg/m3 (6) 1 day average2 98th percentile 35 μg/m3 (7) 35 μg/m3 35 μg/m3 (6) PM-10 24 hour average (40CFR50, App. N) 1 year average2 arithmetic mean 50 μg/m3 50 μg/m3 50 μg/m3 1 day average2 2nd maximum3 150 μg/m3 150 μg/m3 150 μg/m3 CO 1 hour average 8 hours 2nd maximum 9 ppm (10 mg/m3) 9 ppm (10 mg/m3) 1 hour 2nd maximum 35 ppm (40 mg/m3) 35 ppm (40 mg/m3) O3 1 hour average (40CFR50, App. I) 1 hour expected4 2nd maximum 0.12 ppm (6) (235 μg/m3) 0.12 ppm (6) (235 ��g/m3) 0.12 ppm (235 μg/m3) (6,8) 8 hours average5 arithmetic mean 4th maximum 0.08 ppm (6) (157 μg/m3) 0.08 ppm (6) (157 μg/m3) 0.08 ppm (6) (157 μg/m3) SO2 1 hour average 1 year arithmetic mean 0.03 ppm (80 μg/m3) 0.03 ppm (80 μg/m3) 1 day 2nd maximum 0.14 ppm (365 μg/m3) 0.14 ppm (365 μg/m3) 3 hours (non-overlapping) 2nd maximum 0.50 ppm (1,300 μg/m3) 0.50 ppm (1,300 μg/m3) NO2 1 hour average 1 year arithmetic mean 0.053 ppm (100 μg/m3) 0.053 ppm (100 μg/m3) 0.053 ppm (100 μg/m3) Pb 24-hour average 1 quarter arithmetic mean 1.5 μg/m3 1.5 μg/m3 1.5 μg/m3 1. In 1987, National standards for PM-10 replaced those for TSP. 2. Arithmetic mean over the 3 most current years. 3. In July 1997, a percentile-based statistic replaced the 2nd maximum, but in May 1999 the 2nd maximum standard was reinstated. 4. Determined by adjusting for incomplete days and averaging over the most recent 3 consecutive, complete calendar years. 5. Arithmetic mean value over the most recent 3 consecutive, complete calendar years. 6. On April 1, 2000, North Carolina adopted the EPA PM2.5 and Ozone standards. On May 14, 2000, the US Court of Appeals ruled the new EPA PM2.5 standard vacated and the new 8-hour ozone standard as unenforceable. On appeal to the US Supreme Court the new standard was upheld. 7. To attain this standard, the 3-year average of the 98th percentile of 24-hour concentrations at each population-oriented monitor within an area must not exceed 35 μg/m3 (effective December 17, 2006). 8. On May 27, 2000, the one-hour ozone standard was rescinded by the Environmental Management Commission based on EPA guidance. The one-hour standard is being reinstated by EPA. 9 4 Ambient Air Quality Monitoring Program The North Carolina Division of Air Quality, three local air pollution control programs, and one tribal program (Appendix A) performed ambient monitoring and analyses of samples in 2006. Ambient air monitoring data are used to determine whether air quality standards are being met; to assist in enforcement actions; to determine the improvement or decline of air quality; to determine the extent of allowable industrial expansion; and to provide air pollution information to the public. A list of all monitoring sites active in 2006 is presented in Table 4.1 and shown as a map in Figure 4.1. The locations of sites for individual pollutants are shown in Figures 5.1, 5.4, 5.8, 5.11, 5.14, and 5.17. In general, ambient monitors are operated year-round, but in some cases seasonal variations in pollutant levels make it feasible to suspend sampling at certain times. Ambient carbon monoxide associated with transportation and heating tends to produce significant concentrations only in cold weather conditions, so (with the US EPA's permission) we generally operate these monitors only from October through March. Ozone concentrations, by contrast, are correlated positively with ambient temperature. US EPA regulations accordingly require monitoring in NC from April through October. Along with ozone at some locations, we also monitor ozone precursor pollutants. Indeed, one of the ozone precursors is carbon monoxide. See 5.4 for more information about seasonal carbon monoxide monitoring and 5.5 for more information about seasonal ozone monitoring. Siting of monitors involves several considerations, including size of the area represented, distance from roadways and nearby sources, unrestricted air flow, safety, availability of electricity and security. Each site has a defined monitoring objective, and annual evaluations are conducted to ensure that the objectives are met. The four basic monitoring objectives are to determine: the highest concentration expected in an area; representative concentrations in areas of high population density; the impact of significant sources or source categories on ambient air quality; general background concentration levels. All monitors have known precision, accuracy, interferences and operational parameters. The monitors as well as all measurement devices are carefully calibrated at predetermined frequencies, varying from daily to quarterly. Measurements are traceable to National Institute of Standards and Technology (NIST), when standards are available. Monitoring and analyses are performed according to a set of standard operating procedures. Field personnel visit manual 10 sampling sites once every six days to replace sample media and check the operation and calibration of monitors. Personnel check continuous monitors at least twice monthly for correct instrument operation. Monitoring agencies carry out quality assurance activities to determine the quality of the collected ambient data, improve the quality of the data and evaluate how well the monitoring system operates. The goal of quality assurance activities is to produce high quality air pollution data with defined completeness, precision, accuracy, representativeness and comparability. Microprocessors are used at most sites to collect the data. A computerized telemetry system aids in assembly of the data for submission to the US EPA. This enhances data validity, minimizes travel costs, and allows real-time data to be available by computer polling when needed. Numerous checks are performed to ensure that only valid data are reported. Figure 4.1 Monitoring Sites Active in 200611 Table 4.1 Ambient Air Monitoring Sites Operated in North Carolina, 2006 SITE ADDRESS POLLUTANTS COUNTY 37-001-0002 827 S GRAHAM & HOPEDALE RD PM2.5 ALAMANCE BURLINGTON 37-003-0004 106 WAGGIN TRAIL RD O3 ALEXANDER TAYLORSVILLE 37-011-0002 7510 BLUE RIDGE PARKWAY SPUR O3 AVERY LINVILLE 37-013-0006 NC 306 @ PCS ENTRANCE SO2 BEAUFORT AURORA 37-021-0030 ROUT 191 SOUTH BREVARD RD O3 BUNCOMBE ASHEVILLE 37-021-0034 175 BINGHAM ROAD PM2.5 BUNCOMBE ASHEVILLE 37-027-0003 HWY 321 NORTH O3 CALDWELL LENOIR 37-033-0001 7074 CHERRY GROVE RD O3 PM2.5 CO CASWELL REIDSVILLE 37-035-0004 1650 1ST STREET PM10 PM2.5 CATAWBA HICKORY 37-035-0006 320 3RD STREET DR SW PM2.5 CATAWBA HICKORY 37-037-0004 325 RUSSETT RUN ROAD O3 PM2.5 CHATHAM PITTSBORO 37-051-0007 CUMBERLAND CO ABC BOARD, 1705 OWEN DR CO CUMBERLAND FAYETTEVILLE 37-051-0008 1/4 MILE SR1857/US301/1857 O3 CUMBERLAND WADE 37-051-0009 4533 RAEFORD RD PM10 PM2.5 CUMBERLAND FAYETTEVILLE 37-051-1003 3625 GOLFVIEW RD O3 SO2 CUMBERLAND HOPE MILLS 12 SITE ADDRESS POLLUTANTS COUNTY 37-057-0002 SOUTH SALISBURY STREET PM2.5 DAVIDSON LEXINGTON 37-059-0002 246 MAIN STREET O3 DAVIE COOLEEMEE 37-061-0002 HIGHWAY 50 PM2.5 DUPLIN KENANSVILLE 37-063-0001 HEALTH DEPT 300 E MAIN STREET PM10 PM2.5 DURHAM DURHAM 37-063-0013 2700 NORTH DUKE STREET CO O3 DURHAM DURHAM 37-065-0004 900 SPRINGFIELD RD PM2.5 EDGECOME ROCKY MOUNT 37-065-0099 7589 NC HIGHWAY 33 NW O3 PM10 EDGECOME TARBORO 37-067-0022 1300 BLK HATTIE AVENUE PM10 O3 SO2 NO2 PM2.5 FORSYTH WINSTON-SALEM 37-067-0023 1401 CORPORATION PARKWAY CO PM10 FORSYTH WINSTON-SALEM 37-067-0028 6496 BAUX MOUNTAIN ROAD O3 FORSYTH WINSTON-SALEM 37-067-0030 FRATERNITY CHURCH O3 PM2.5 FORSYTH WINSTON-SALEM 37-067-1008 3656 PIEDMONT MEMORIAL DRIVE O3 FORSYTH WINSTON-SALEM 37-069-0001 431 S. HILLSBOROUGH STREET O3 FRANKLIN FRANKLINTON 37-071-0016 1622 EAST GARRISON BLVD PM2.5 GASTON GASOTNIA 37-075-0001 FOREST ROAD 423 SPUR O3 GRAHAM KILMER 13 SITE ADDRESS POLLUTANTS COUNTY 37-077-0001 WATER TREATMENT PLANT JOHN UMSTEAD HOSP O3 GRANVILLE BUTNER 37-081-0013 205 WILOUGHBY BLVD PM2.5 PM10 O3 GUILFORD GREENSBORO 37-081-1011 401 WEST WENDOVER CO GUILFORD GREENSBORO 37-087-0004 2177 ASHEVILLE ROAD O3 HAYWOOD WAYNESVILLE 37-087-0010 9 MAIN STREET PM2.5 HAYWOOD WAYNESVILLE 37-087-0035 TOWER BLUE RIDGE PARKWAY O3 HAYWOOD MILE MARKER 410 37-087-0036 GREAT SMOKY MOUNTAINS O3 HAYWOOD NATIONAL PARK 37-089-1006 CORNER OF ALLEN & WASHINGTON ST'S PM10 HENDERSON HENDERSONVILLE 37-099-0005 BARNET KNOB FIRE TOWER RD O3 JACKSON CHEROKEE 37-099-0006 US ROUTE 19 NORTH PM2.5 JACKSON CHEROKEE RESERVATION 37-101-0002 1338 JACK ROAD O3 JOHNSTON CLAYTON 37-107-0004 HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH O3 PM2.5 LENOIR KINSTON 37-109-0004 1487 RIVERVIEW ROAD O3 LINCOLN LINCOLNTON 37-111-0004 BALWIN AVENUE (EAST MARION JR. HIGH SCHOOL) PM2.5 MC DOWELL MARION 37-117-0001 1210 HAYES STREET O3 PM2.5 SO2 MARTIN JAMESVILLE 14 SITE ADDRESS POLLUTANTS COUNTY 37-119-0003 FIRE STATION # 11, 620 WEST 28TH STREET PM10 MECKLENBURG CHARLOTTE 37-119-0041 1130 EASTWAY DRIVE CO SO2 PM2.5 O3 NO2 MECKLENBURG CHARLOTTE 37-119-0042 1935 EMERYWOOD DRIVE PM2.5 MECKLENBURG CHARLOTTE 37-119-043 513 RADIO ROAD PM2.5 MECKLENBURG 37-119-1001 FILTER PLANT PM10 MECKLENBURG DAVIDSON 37-119-1005 400 WESTINGHOUSE BLVD. O3 PM10 MECKLENBURG CHARLOTTE 37-119-1009 29 N @ MECKLENBURG CAB CO. O3 MECKLENBURG CHARLOTTE 37-121-0001 CITY HALL, SUMMIT STREET PM2.5 MITCHELL SPRUCE PINE 37-123-0001 112 PERRY DRIVE PM2.5 MONTGOMERY CANDOR 37-129-0002 6028 HOLLY SHELTER ROAD O3 PM2.5 NEW HANOVER CASTLE HAYNE 37-129-0006 HIGHWAY 421 NORTH SO2 NEW HANOVER WILMINGTON 37-133-0005 617 HENDERSON DR PM2.5 PM10 ONSLOW JACKSONVILLE 37-135-0007 MASON FARM ROAD PM2.5 ORANGE CHAPEL HILL 37-145-0003 STATE ROAD 1102 & NC 49 O3 PERSON ROXBORO 37-147-0005 851 HOWELL STREET PM2.5 PITT GREENVILLE 37-147-0099 US 264 NEAR WATER TOWER O3 PITT FARMVILLE 15 SITE ADDRESS POLLUTANTS COUNTY 37-155-0005 1170 LINKHAW ROAD PM2.5 ROBESON LUMBERTON 37-157-0099 6371 NC 65 @ BETHANY SCHOOL O3 ROCKINGHAM BETHANY 37-159-0021 301 WEST ST & GOLD HILL AVENUE CO O3 PM2.5 ROWAN ROCKWELL 37-159-0022 925 NORTH ENOCHVILLE AVENUE O3 ROWAN CHINA GROVE 37-173-0002 CENTER ST/PARKS & RECREATION FACILITY O3 PM2.5 PM10 SWAIN BRYSON CITY 37-179-0003 701 CHARLES STREET O3 UNION MONROE 37-183-0014 3801 SPRING FOREST ROAD O3 PM2.5 PM10 SO2 CO WAKE RALEIGH 37-183-0016 201 NORTH BROAD STREET O3 WAKE FUQUAY-VARINA 37-183-0018 US HIGHWAY 70 WEST AND NC HIGHWAY 50 NORD CO WAKE RALEIGH 37-189-0003 361 JEFFERSON ROAD PM2.5 WATAUGA BOONE 37-191-0005 DILLARD MIDDLE SHOOL, DEVEREAU STREET PM2.5 PM10 WAYNE GOLDSBORO 37-199-0003 STATE HIGHWAY 128 O3 YANCEY BURNSVILLE 37-199-0004 NEW LOC MT MITCHELL O3 YANCEY Sites operated in 74 2006 16 5 Pollutant Monitoring Results Air quality in a given area is affected by many factors, including meteorological conditions, the location of pollutant sources, and the amount of pollutants emitted from them. The speed and direction of air movement determine whether pollutant emissions cause exceedances of the ambient air quality standards and where those exceedances will occur. Atmospheric stability, precipitation, solar radiation and temperature also affect pollutant concentrations. Geographic factors that affect concentrations include variables such as whether an area is urban or rural, and whether the area has mountains, valleys or plains. Important economic factors affecting air quality include concentration of industries, conditions of the economy, and the day of the week. Air quality also may be influenced by “exceptional events” in the short term. Exceptional events may be either natural (e.g., forest fire) or manmade (e.g., construction or demolition). Unusual data that can be attributed to an exceptional event are considered biased and may be omitted from data summaries when they are not representative of normal conditions. In the tabular listings in this report, data affected by exceptional events are excluded, and are omitted from summaries in charts. However they are addressed in the text of the report. A list of typical exceptional events is given in Appendix B. Data for the 2006 ambient air quality report were collected at 122 air pollutant monitors operated by state and local agencies in North Carolina (listed in Appendix A). To minimize operating expenses, some sulfur dioxide monitors are operated only every third year. Four of the 122 monitors used for this report operated most recently in 2004 or 2005. 5.1 Total Suspended Particulates Total Suspended Particulate matter (TSP) is collected on filters using a “high volume” sampler (an EPA Reference Method). The sampler motor is set and calibrated to an air flow rate of 40±4 cubic feet per minute. Gravimetric analysis is performed by comparing the exposed filter weight to the unexposed filter weight. Weights are measured to the nearest 0.1 milligram. The difference between the exposed and unexposed weights is the amount of particulate collected from a known volume of air. The state and local program agencies discontinued routine ambient TSP sampling at the end of 2000, but resumed a limited sampling program again in 2003. In 2006 seven sites were used to monitor TSP and 361 samples were collected. A detailed summary of 17 the data from each site is given in Table 5.1. No sample exceeded the N.C. TSP ambient air quality standards in 2006. The highest 24-hour average was 69 g/m3 , which was 46 percent of the standard. This value occurred at the 6028 Holly Shelter Road site in Castle Hayne. Attainment status is based on the second highest 24-hour concentration and on the geometric mean of all the 24-hour concentrations at a given site. The largest geometric mean TSP average was 29 g/m3, which is 39 percent of the level of the air quality standard. This value occurred at the 1650 1st Street site in Hickory and 205 Willoughby Boulevard site in Greensboro. Table 5.1 Total Suspended Particulates in Micrograms Per Cubic Meter for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAX ARITH MEAN GEOM MEAN GEOM SD COUNTY 1st 2nd 3rd 4th 37-035-0004 1650 1st STREET 53 68 60 55 53 33 29 1.7 CATAWBA HICKORY 37-081-0013 205 WILLOUGHBY BLVD 42 65 55 52 52 32 29 1.6 GUILFORD GREENSBORO 37-087-0011 HAYWOOD PROSPECT AND NORTHSIDE STR 58 62 50 50 49 29 26 1.7 CANTON 37-117-0001 1210 HAYES STREET 60 46 43 37 35 22 20 1.4 MARTIN JAMESVILLE 37-129-0002 6028 HOLLY SHELTER RD 56 69 40 36 35 21 19 1.6 NEW HANOVER CASTLE HAYNE 37-155-0005 1170 LINKHAW ROAD 56 57 49 48 43 28 25 1.7 ROBESON LUMBERTON 37-183-0014 3801 SPRING FOREST RD 36 65 58 52 51 34 32 1.5 WAKE RALEIGH Total Samples 361 Total Sites Sampled 7 18 5.2 PM10 State and local program agencies in North Carolina use high volume samplers and size selective inlets to collect PM10 samples. A gravimetric analysis procedure (EPA Reference Method) is used to analyze the samples. In 2006, 1,717 ordinary 24-hour samples of PM10 were collected from monitors located at 15 sites. A map of the PM10 sampling sites is shown in Figure 5.1, and a detailed summary of the data from each site is given in Table 5.2. There were no exceedances of the PM10 ambient air quality standards in 2006. The highest 24-hour maximum concentration was 69 g/m3, or about 46 percent of the standard (150 g/m3). The highest annual arithmetic mean was 31.1 g/m3, which is about 62 percent of the standard (50 g/m3). The second highest 24-hour concentrations are shown by county in Figure 5.2 and the annual arithmetic means are shown in Figure 5.3. (In counties with more than one PM10 monitoring site, the concentration reported in Figure 5.2 is the county-wide second maximum 24-hour concentration, and the mean reported in Figure 5.3 is the maximum arithmetic mean for the county.) Figure 5.1 Location of PM10 Monitoring Sites 19 Table 5.2 PM10 in Micrograms Per Cubic Meter for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-035-0004 1650 1ST. ST. 59 56 45 44 42 21.6 CATAWBA HICKORY 37-051-0009 CUMBERLAND 4533 RAEFORD ROAD 60 41 40 35 35 18.8 FAYETTEVILLE 37-063-0001 DURHAM HEALTH DEPT 300 E MAIN ST 60 38 31 31 30 18.1 DURHAM 37-065-0099 7589 NC HWY 33 NW 59 45 38 36 34 15.9 EDGECOMBE LEGGETT 37-067-0022 1300 BLK. HATTIE AVE 365 51 45 41 41 19.4 FORSYTH WINSTON-SALEM 37-067-0023 FORSYTH 1401 CORPORATION PARKWAY 362 53 51 47 47 23.0 WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 46 43 33 32 21.2 GUILFORD GREENSBORO 37-089-1006 HENDERSON CORNER OF ALLEN & WASHINGTON STS 59 52 42 35 35 20.4 HENDERSONVILLE 37-119-0003 MECKLENBURG FIRE STA #11 620 MORETZ STREET 60 47 46 44 44 25.5 CHARLOTTE 37-119-1001 FILTER PLANT 58 53 42 41 40 22.2 MECKLENBURG DAVIDSON 37-119-1005 400 WESTINGHOUSE BLVD. 60 69 62 56 54 31.1 MECKLENBURG CHARLOTTE 37-133-0005 617 HENDERSON DRIVE 60 44 38 31 29 16.1 ONSLOW JACKSONVILLE 37-173-0002 CENTER ST/PARKS 7 REC 59 53 40 31 31 17.9 SWAIN FACILITY 37-183-0014 3801 SPRING FOREST RD. 300 43 43 41 39 19.5 WAKE RALEIGH 37-191-0005 WAYNE DILLARD MIDDLE SCHOOL DEVEREAU ST 53 41 34 31 30 18.2 GOLDSBORO Total Samples 1,717 Total Sites Sampled 15 20 Figure 5.2 PM10: Second Highest 24-Hour Averages, 2006 Figure 5.3 PM10: Maximum Annual Arithmetic Means, 2006 21 5.3 Fine Particulate Matter, (PM2.5) In 2006, 35 sites were used to monitor PM2.5 and 5,176 samples were collected. A map of the PM2.5 sampling sites is shown in Figure 5.4 and a detailed summary of the data from each site is given in Table 5.3. There was one exceedance of the PM2.5 24-hour ambient air quality standards in 2006, at the Perry Drive site in Montgomery County. This highest 24-hour concentration was 69.2 g/m3, or about 6 percent of the 2005 standard (65 g/m3), but according to a new implemented standard in 2006 (35 g/m3) there were 17 exceedances of the PM2.5 24-hr ambient air quality standard (See Table 5.3). The highest annual arithmetic mean was 15.16 g/m3, which is about 1 percent over the level of the standard (15 g/m3), at Hickory in Catawba County. The other monitor that exceeded the annual arithmetic mean standard in 2006 was South Salisbury Street in Davidson County. (See Table 5.3). NAAQS attainment is based on both the level of the 98th percentile concentration of 24 hour averages and weighted annual means (Table 3.1). The 98th percentile concentrations are shown by county in Figure 5.5, and the annual arithmetic means are shown in Figure 5.6. (In counties with more than one monitoring site, the concentration reported in Figure 5.5 is the maximum 98th percentile and the mean reported in Figure 5.6 is the maximum arithmetic mean for the county.) Figure 5.7 is a map of “design values” for PM2.5, computed from the highest 3-year average arithmetic mean in each county for 2004 through 2006, using the federal reference method monitors. Thirty-one counties have enough reported data to compute this metric correctly, and two of them appear to be violating the ambient standard that is due to be implemented. Attainment decisions for PM2.5 will be based on the design values observed during 2004 through 2006, which may or may not resemble the values illustrated here. 22 Figure 5.4 Location of PM2.5 Monitoring Sites Table 5.3 PM2.5 in Micrograms Per Cubic Meter for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA PERCENTILE ARITH MEAN COUNTY 1st 2nd 3rd 4th 98TH 37-001-0002 ALAMANCE 827 S. GRAHAM & HOPEDALE RD 120 35.2 35.2 28.7 28.3 28.7 13.52 BURLINGTON 37-021-0034 BUNCOMBE 175 BINGHAM ROAD 120 35.5 31.5 30.9 30.3 30.9 12.51 ASHEVILLE 37-033-0001 CASWELL 7074 CHERRY GROVE RECREATION 119 32.3 30.9 29.9 29.7 29.9 13.29 37-035-0004 1650 1ST. ST. 122 38.1 34.4 32.9 32.7 32.9 15.16 CATAWBA HICKORY 37-035-0006 320 3RD ST DR SW 58 31.6 27.0 26.9 25.8 27.0 13.50 CATAWBA HICKORY 37-037-0004 325 RUSSETT 117 34.4 32.3 28.4 28.2 28.4 12.29 CHATHAM PITTSBORO 37-051-0009 CUMBERLAND 4533 RAEFORD ROAD 121 33.2 30.1 30.0 28.9 30.0 13.60 FAYETTEVILLE 37-057-0002 DAVIDSON SOUTH SALISBURY STREET 120 40.2 31.3 31.0 31.0 31.0 15.13 LEXINGTON 23 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA PERCENTILE ARITH MEAN COUNTY 1st 2nd 3rd 4th 98TH 37-061-0002 HWY 50 116 30.0 29.4 27.5 25.3 27.5 11.06 DUPLIN KENANANSVILLE 37-063-0001 DURHAM HEALTH DEPT 300 E MAIN ST 339 36.5 35.2 34.4 32.3 30.0 13.65 DURHAM 38-065-0004 900 SPRINGFIELD 117 41.8 32.5 27.0 26.9 27.0 12.79 EDGECOMBE ROCKY MOUNT 37-067-0022 FORSYTH 1300 BLOCK, HATTIE AVENUE 302 43.3 33.2 32.8 32.3 30.8 14.18 WINSTON-SALEM 37-067-0030 FORSYTH FRATERNITY CHURCH ROAD 113 32.6 32.3 31.8 30.7 31.8 14.11 WINSTON-SALEM 37-071-0016 GASTON 1622 EAST GARRISON BLVD 119 36.3 32.2 29.5 28.9 29.5 14.30 GASTONIA 37-081-0013 GUILFORD 205 WILOUGHBY BLVD 235 39.4 34.2 32.9 31.8 31.3 14.44 GREENSBORO 37-087-0010 9 MAIN STREET 119 33.4 30.6 30.2 28.8 30.2 12.76 HAYWOOD WAYNESVILLE 37-099-0006 US RT 19 NORTH 107 27.6 25.2 24.4 24.1 24.4 11.84 JACKSON CHEROKEE RES 37-107-0004 LENOIR CORNER HWY 70 EAST 116 31.0 25.7 23.3 22.2 23.3 10.51 KINSTON 37-111-0004 BALDWIN AVE 119 36.9 33.8 32.2 30.8 32.2 13.76 MC DOWELL MARION 37-117-0001 1210 HAYES ST 114 35.6 26.3 24.2 23.4 24.2 10.66 MARTIN JAMESVILLE 37-119-1041 MECKLENBURG 1130 EASTWAY DRIVE 350 35.8 35.5 33.9 33.0 30.7 14.59 CHARLOTTE 37-119-1042 MECKLENBURG 1935 EMERYWOOD DRIVE 119 35.7 33.5 31.5 30.7 31.5 14.63 CHARLOTTE 37-119-0043 MECKLENBURG 513 RADIO ROAD 336 35.7 34.0 33.8 31.9 29.9 13.95 37-121-0001 MITCHELL CITY HALL SUMMIT ST 120 33.5 31.0 30.9 30.3 30.9 12.25 SPRUCE PINE 37-123-0001 112 PERRY DRIVE 120 69.2 29.7 29.2 28.8 29.2 12.37 MONTGOMERY CANDOR 24 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA PERCENTILE ARITH MEAN COUNTY 1st 2nd 3rd 4th 98TH 37-129-0002 NEW HANOVER 6028 HOLLY SHELTER RD 118 27.1 27.0 25.8 22.7 25.8 9.75 37-133-0005 ONSLOW 617 HENDERSON DRIVE 118 28.3 25.5 24.6 23.4 24.6 10.56 JACKSONVILLE 37-135-0007 ORANGE MASON FARM ROAD 122 33.6 32.3 31.3 28.6 31.3 12.95 CHAPEL HILL 37-147-0005 PITT 851 HOWELL STREET 116 36.1 28.6 25.3 24.1 25.3 11.14 GREENVILLE 37-155-0005 ROBESON 1170 LINKHAM ROAD 121 33.2 30.3 28.4 27.8 28.4 12.49 LUMBERTON 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 119 36.9 33.5 29.1 29.1 29.1 14.22 ROCKWEL 37-173-0002 SWAIN CENTER ST/PARKS 7 REC 118 29.0 27.0 26.7 26.6 26.7 11.87 FACILITY 37-183-0014 WAKE 3801 SPRING FOREST RD 250 27.7 26.4 25.5 24.5 24.4 12.27 RALEIGH 37-189-0003 WATAUGA 361JEFFERSON HWY 119 30.5 29.8 29.2 28.5 29.2 11.24 BOONE 37-191-0005 WAYNE DILLARD MIDDLE SCHOOL 117 35.1 32.6 32.5 27.3 32.5 12.90 GOLDSBORO Total Samples 5,176 Total Sites Sampled 35 25 Figure 5.5 PM2.5: 98th Percentile, 2006 Figure 5.6 PM2.5: Annual Arithmetic Means, 2006 26 Figure 5.7 PM2.5 Design Values by County, 2004-2006 27 5.4 Carbon Monoxide Carbon monoxide (CO) data were collected for two purposes in 2006: to determine attainment status of the ambient air quality standard, and to gather data on CO as an ozone precursor. The carbon monoxide associated with ozone formation consists of very low concentrations (not greater than 2 ppm) collected at special sites considered optimal for input to a large photochemical grid model. This report will not further discuss the role of CO as an ozone precursor, but these data and more information are available on request from the Division of Air Quality (see the Preface for a mailing address). To assess CO attainment status, the Division of Air Quality collected data from monitors in Durham, Greensboro and Raleigh, and local program agencies collected data from three monitors in Winston-Salem and Charlotte using EPA Reference or equivalent methods to measure the concentrations. In 2006, five sites were used to monitor CO and 28,259 valid hourly averages were collected. The data were collected from monitors: - Charlotte, Winston-Salem-all year; - Greensboro, Raleigh and Fayetteville – colder months. A map of the CO sampling sites is shown in Figure 5.8, and a detailed summary of the data from each site is presented in Table 5.4. There were no exceedances of the CO ambient air quality standards in 2006. The highest 1-hour average was 4.0 parts per million (ppm), or about 11 percent of the standard (35 ppm). This value occurred at the ABC Board site in Fayetteville. The highest 8-hour average was 3.0 ppm, at the ABC Board site in Fayetteville, which is about 33 percent of the standard. The second highest 1-hour concentrations in each county are shown in Figure 5.9 and the second highest 8-hour concentrations are shown in Figure 5.10. Historical data have demonstrated that high concentrations of CO occur more frequently in autumn and winter than during the warmer months of the year. There are three main reasons for this seasonal variation: (1) North Carolina experiences more atmospheric inversions in colder months, trapping air pollutants at low heights; (2) motor vehicles emit more CO due to inefficient combustion during cold starts and warm up; and (3) during colder temperatures, more fuel is burned for comfort heating. All areas monitored are attaining the ambient air quality standards for carbon monoxide. Several factors have reduced CO concentrations, with the most significant being that older vehicles are gradually being replaced with newer, more efficient vehicles. The motor vehicle Inspection and Maintenance program (in effect in 48 counties [NC Dept of Environmental and Natural Resources, N.D]) is an intentional control strategy that helps assure cleaner-running cars. Other factors include increased news media interest and public awareness, and the reporting of the Air Quality Index (see Chapter 6 of this report). As a result of greater public awareness, more cars are kept in better running condition, thus operating more cleanly. Traffic flow improvements such as new roads and better coordinated traffic signals also help reduce CO. 28 Figure 5.8 Location of Carbon Monoxide Monitoring Sites Table 5.4 Carbon Monoxide in Parts Per Million for 2006 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA EIGHT-HOUR MAXIMA COUNTY 1st 2nd 1st 2nd 37-051-0007 ABC BOARD, 1705 OWEN DRIVE 3,641 4.0 3.8 3.0 2.7 CUMBERLAND FAYETTEVILLE 37-067-0023 1401 CORPORATION PKY 8,700 3.2 3.2 2.7 2.4 FORSYTH WINSTON-SALEM 37-081-1011 401 WEST WENDOVER 3,552 2.9 2.8 2.6 2.5 GUILFORD GREENSBORO 37-119-0041 1130 EASTWAY DRIVE 8,656 3.6 3.0 2.3 2.3 MECKLENBURG CHARLOTTE 37-183-0018 WAKE US HWY 70 WEST AND NC HWY 50 NORTH 3,710 3.3 3.3 2.6 2.5 RALEIGH Total Samples 28,259 Total Sites Sampled 5 29 Figure 5.9 Carbon Monoxide: Second Highest 1-Hour Concentration, 2006 Figure 5.10 Carbon Monoxide: Second Highest Non-overlapping 8-Hour Concentration, 2006 30 5.5 Ozone Ozone (O3) concentrations are measured using EPA reference or equivalent continuous monitors. Ozone is a seasonal pollutant formed in the atmosphere as a result of many chemical reactions that occur in sunlight, mainly during the warmer months. Thus, most ozone monitors only operate from April through October. The state and local program agencies operated 42 monitoring sites in 2006 during the ozone season, April through October. A map of the O3 sampling sites is presented in Figure 5.11, and a detailed summary of the one-hour data from each site is given in Table 5.5, and the 8-hour data in Table 5.6. These 42 monitoring sites provided 8,392 site-days of valid data (a success rate of 93 percent for the days that sampling is required). There were no exceedances of the 1-hour ozone standard in North Carolina in 2006. The one-hour standard is exceeded when one valid one-hour average exceeds 0.124 ppm at a site and the expected number of exceedances is greater than 1. (To exceed the standard, the largest average must be larger than 0.12 ppm when rounded to two significant digits. The “expected number” of exceedances is determined from a 3-year average of exceedance day counts for an area. Moreover, when any ozone sampling day does not have a valid maximum ozone measurement for any reason, the missing day can be counted as an estimated exceedance day under certain circumstances [40 CFR 50 App. J, US EPA 1993, p. 767-768]. Table 5.5 gives both the actually measured and the estimated number of exceedance days at each site.) The 8-hour standard was exceeded a total of 48 times at the 42 sites that monitored for O3. Eighteen monitors had at least one exceedance. The largest number at one monitor was eight in Charlotte (Mecklenburg County). These exceedances were distributed over 20 days during the ozone season when at least one site within the state recorded values greater than 0.085 ppm. The second highest 1-hour concentrations in each county are shown in Figure 5.12 for areas with one or more monitors active in 2006. Monitors whose second highest 1-hour concentration exceeds 0.124 ppm potentially violate the EPA one-hour standard (although it is no longer in effect in North Carolina). Historical average fourth-highest 8-hour concentrations of O3 in counties where monitors were operated in 2006 are shown in Figure 5.13. Monitors whose fourth-highest 8-hour ozone concentration (averaged over three years) exceeds 0.084 ppm are deemed in violation of the EPA 8-hour standard.31 Figure 5.11 Location of Ozone Monitoring Sites Table 5.5 One-Hour Ozone in Parts Per Million for 2006 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST 37-003-0004 106 WAGGIN’ TRAIL 5136 .094 .091 .089 .088 0 0.00 ALEXANDER TAYLORSVILLE 37-011-0002 7510 BLUE RIDGE 4896 .079 .076 .071 .070 0 0.00 AVERY 37-021-0030 ROUTE 191 SOUTH BREVARD RD 5136 .092 .090 .083 .082 0 0.00 BUNCOMBE ASHEVILLE 37-027-0003 HWY 321 NORTH 5088 .095 .088 .087 .084 0 0.00 CALDWELL LENOIR 37-033-0001 7074 CHERRY GROVE 4968 .092 .089 .086 .086 0 0.00 32 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST CASWELL REIDSVILLE 37-037-0004 325 RUSSETT RUN ROAD 5112 .094 .084 .082 .080 0 0.00 CHATHAM PITTSBORO 37-051-0008 1/4MI SR1857/US301/1857 5040 .090 .083 .083 .082 0 0.00 CUMBERLAND WADE 37-051-1003 3625 GOLFVIEW ROAD 5088 .093 .091 .085 .085 0 0.00 CUMBERLAND HOPE MILLS 37-059-0002 246 MAIN STREET 5136 .103 .096 .093 .093 0 0.00 DAVIE COOLEEMEE 37-063-0013 2700 NORTH DUKE STREET 5088 .103 .097 .091 .085 0 0.00 DURHAM DURHAM 37-065-0099 7589 NC HWY 33-NW 5136 .093 .087 .084 .081 0 0.00 EDGECOMBE LEGGETT 37-067-0022 1300 BLK. HATTIE AVENUE 5136 .098 .097 .097 .096 0 0.00 FORSYTH WINSTON-SALEM 37-067-0028 6496 BAUX MOUNTAIN ROAD 5136 .087 .085 .078 .075 0 0.00 FORSYTH WINSTON-SALEM 37-067-0030 FRATERNITY CHURCH ROAD 5136 .105 .094 .089 .087 0 0.00 FORSYTH WINSTON-SALEM 37-067-1008 3656 PIEDMONT MEMORIAL DRIVE 5136 .105 .100 .098 .092 0 0.00 FORSYTH WINSTON-SALEM 37-069-0001 431 S. HILLBOROUGH ST 5136 .105 .091 .090 .088 0 0.00 FRANKLIN FRANKLINTON 37-075-0001 FOREST ROAD 423 SPUR 5088 .109 .090 .087 .086 0 0.00 GRAHAM KILMER 37-077-0001 WATER TREATMENT PLANT, JOHN UMSTEAD HOSPITAL 5112 .108 .095 .093 .093 0 0.00 GRANVILLE BUTNER 37-081-0013 205 WILOUGHBY BLVD 4104 .113 .101 .093 .092 0 0.00 GUILFORD GREENSBORO 33 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST 37-087-0004 2177 SCHEVILLS ROAD 5136 .083 .082 .076 .075 0 0.00 HAYWOOD WAYNESVILLE 37-087-0035 TOWER BLUE RIDGE PARKWAY 4944 .104 .092 .090 .087 0 0.00 HAYWOOD MILE MARKER 410 37-087-0036 GREAT SMOKY MOUNTAIN 4920 .092 .088 .081 .079 0 0.00 HAYWOOD NATIONAL PARK 37-099-0005 BARNET KNOB FIRE TOWER 4896 .091 .088 .085 .085 0 0.00 JACKSON CHEROKEE 37-101-0002 1338 JACK ROAD 5112 .089 .088 .084 .083 0 0.00 JOHNSTON CLAYTON 37-107-0004 CORNER HWY EAST 4920 .095 .087 .085 .083 0 0.00 LENOIR KINSTON 37-109-0004 1487 RIVERVIEW ROAD 5088 .119 .113 .101 .095 0 0.00 LINCOLN LINCOLNTON 37-117-0001 1210 HAYES STREET 5088 .086 .082 .081 .080 0 0.00 MARTIN JAMESVILLE 37-119-0041 1130 EASTWAY DRIVE 5112 .122 .112 .110 .107 0 0.00 MECKLENBURG CHARLOTTE 37-119-1005 400 WESTINGHOUSE BLVD. 5136 .105 .097 .097 .097 0 0.00 MECKLENBURG CHARLOTTE 37-119-1009 29 N@ MECKLENBURG CAB CO 5112 .120 .115 .107 .106 0 0.00 MECKLENBURG CHARLOTTE 37-129-0002 6028 HOLLY SHELTER RD 5016 .088 .085 .085 .081 0 0.00 NEW HANOVER CASTLE HAYNE 37-145-0003 STATE ROAD 1102 & NC49 5136 .096 .090 .089 .086 0 0.00 PERSON ROXBORO 37-147-0099 US 264 NEAR WATTER TOWER 5136 .102 .083 .083 .081 0 0.00 PITT FARMVILLE 34 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST 37-157-0099 6371 NC 65 @ BETHANY SCHOOL 5136 .097 .091 .089 .088 0 0.00 ROCKINGHAM BETHANY 37-159-0021 301 WEST ST & GOLD HILL AVENUE 5136 .119 .104 .101 .098 0 0.00 ROWAN ROCKWELL 37-159-0022 925 N ENOCHVILLE AVE 5136 .111 .110 .109 .107 0 0.00 ROWAN CHINA GROVE 37-173-0002 CENTER STREET 5112 .072 .070 .070 .069 0 0.00 SWAIN BRYSON CITY 37-179-0003 701 CHARLES STREET 3984 .115 .111 .097 .092 0 0.00 UNION MONROE 37-183-0014 3801 SPRING FOREST ROAD 4872 .101 .093 .091 .090 0 0.00 WAKE RALEIGH 37-183-0016 201 NORTH BROAD STREET 5064 .098 .088 .084 .083 0 0.00 WAKE FUQUAY-VARINA 37-199-0003 STATE HIGHWAY 128 1248 .094 .084 .076 .071 0 0.00 YANCY 37-199-004 YANCY BURNSVILLE NEW LOC MT 3432 .091 .084 .084 .080 0 0.00 Total Samples 205,680 0 0.00 Total Sites Sampled 42 35 Table 5.6 Eight-Hour Ozone in Parts Per Million for 2006 SITE NUMBER ADDRESS VALID DAYS VALID DAILY 8-HR MAXIMUM N0. VALUES COUNTY .>.085 1st 2nd 3rd 4th MEAS 37-003-0004 106 WAGGIN’ TRAIL 201 .082 .082 .077 .076 0 ALEXANDER TAYLORSVILLE 37-011-0002 7510 BLUE RIDGE 200 .072 .070 .068 .067 0 AVERY 37-021-0030 ROUT 191 SOUTH BREVARD RD 214 .083 .078 .071 .071 0 BUNCOMBE ASHEVILLE 37-027-0003 HWY 321 NORTH 207 .081 .077 .076 .076 0 CALDWELL LENOIR 37-033-0001 7074 CHERRY GROVE RD 205 .077 .077 .075 .075 0 CASWELL REIDSVILLE 37-037-0004 325 RUSSETT RUN 211 .078 .074 .071 .070 0 CHATHAM PITTSBORO 37-051-0008 1/4MI SR1857/US301/1857 198 .080 .073 .072 .072 0 CUMBERLAND WADE 37-051-1003 3625 GOLFVIEW ROAD 210 .077 .075 .074 .074 0 CUMBERLAND HOPE MILLS 37-059-0002 246 MAIN STREET 213 .086 .083 .083 .080 1 DAVIE COOLEEMEE 37-063-0013 2700 NORTH DUKE STREET 211 .089 .083 .080 .077 1 DURHAM DURHAM 37-065-0099 7589 NC HWY 33-NW 207 .077 .076 .074 .074 0 EDGECOMBE LEGGETT 37-067-0022 1300 BLK. HATTIE AVENUE 214 .090 .085 .083 .082 2 FORSYTH WINSTON-SALEM 37-067-0028 6496 BAUX MOUNTAIN RD 213 .072 .069 .069 .067 0 FORSYTH WINSTON-SALEM 37-067-0030 FRATERNITY CHURCH ROAD 214 .089 .082 .081 .077 1 FORSYTH WINSTON-SALEM 37-067-1008 3656 PIEDMONT MEMORIAL 214 .091 .089 .088 .082 3 FORSYTH DRIVE WINSTON-SALEM 37-069-0001 431 S. HILLBOROUGH ST 211 .091 .076 .075 .074 1 FRANKLIN FRANKLINTON 37-075-0001 FOREST ROAD 423 SPUR 207 .082 .080 .080 .076 0 GRAHAM KLIMER 37-077-0001 WATER TREATMENT PLANT 204 .096 .082 .081 .076 1 GRANVILLE JOHN UMSTEAD HOSPITAL BUTNER 36 SITE NUMBER ADDRESS VALID DAYS VALID DAILY 8-HR MAXIMUM N0. VALUES COUNTY .>.085 1st 2nd 3rd 4th MEAS 37-081-0013 205 WILOUGHBY 164 .088 .086 .080 .080 2 GUILFORD GREENSBORO 37-087-0004 2177 SHEVILLE ROAD 213 .070 .069 .069 .069 0 HAYWOOD WAYNESVILLE 37-087-0035 TOWER BLUE RIDGE PARKWAY 200 .087 .081 .080 .079 1 HAYWOOD MILE MARKER 410 37-087-0036 GREAT SMOKY MOUNTAIN 204 .078 .077 .074 .073 0 HAYWOOD NATIONAL PARK 37-099-0005 BARNET KNOB FIRE TOWER 200 .085 .084 .083 .081 1 JACKSON 37-101-0002 1338 JACK ROAD 211 .078 .076 .073 .072 0 JOHNSTON CLAYTON 37-107-0004 CORNER HWY 70 EAST 194 .081 .080 .074 .071 0 LENOIR KINSTON 37-109-0004 1487 RIVERVIEW ROAD 208 .096 .095 .089 .082 3 LINCOLN LINCOLNTON 37-117-0001 1210 HAYES STREET 208 .076 .072 .071 .070 0 MARTIN JAMESVILLE 37-119-0041 1130 EASTWAY DRIVE 213 .103 .099 .094 .091 7 MECKLENBURG CHARLOTTE 37-119-1005 400 WESTINGHOUSE BLVD. 214 .098 .082 .081 .078 1 MECKLENBURG CHARLOTTE 37-119-1009 29 N@ MECKLENBURG CAB CO 213 .102 .095 .094 .093 8 MECKLENBURG CHARLOTTE 37-129-0002 6028 HOLLY SHELTER RD 192 .079 .076 .072 .070 0 NEW HANOVER 37-145-0003 SR NC 49 214 .079 .076 .076 .075 0 PERSON 37-147-0099 US 264 NEAR WATER TOWER 202 .081 .077 .076 .072 0 PITT FARMVILLE 37-157-0099 6371 NC 65 @ BETHANY SCHOOL 212 .088 .078 .077 .075 1 ROCKINGHAM BETHANY 37-159-0021 301 WEST ST & GOLD HILL AVE 195 .088 .087 .085 .085 5 ROWAN ROCKWELL 37-159-0022 925 N ENOCHVILLE AVE 214 .098 .096 .089 .089 7 ROWAN ENOCHVILLE 37-173-0002 CENTER STREET 207 .068 .066 .065 .063 0 SWAIN PARKS 7 REC FACILITY 37-179-0003 701 CHARLES STREET 165 .096 .095 .083 .080 2 UNION MONROE 37-183-0014 E. MILLBROOK JR HI 197 .083 .080 .080 .078 0 WAKE 3801 SPRING FOREST ROAD 37 SITE NUMBER ADDRESS VALID DAYS VALID DAILY 8-HR MAXIMUM N0. VALUES COUNTY .>.085 1st 2nd 3rd 4th MEAS 37-183-0016 201 NORTH BROAD STREET 210 .082 .075 .074 .073 0 WAKE FUQUAY-VARINA 37-199-0003 STATE HIGHWAY 128 50 .079 .077 .069 .067 0 YANCY 37-199-0004 NEW LOC MT MITCHELL 138 .077 .075 .075 .074 0 YANCEY Total Samples 8,392 48 Total Sites Sampled 42 38 Figure 5.12 Ozone: Second Highest Annual 1-Hour Average, 2006 Figure 5.13 Ozone: Mean Annual Fourth Highest 8-Hour Average, 2004-2006 39 5.6 Sulfur Dioxide Sulfur dioxide (SO2) concentrations were measured by the state and two local program agencies using EPA reference or equivalent methods. Eight SO2 monitors were active in North Carolina in 2006. Some SO2 sites are operated only every third year. We supplemented this report with one monitor that operated last in 2005, (and will next be operated in 2008), and three monitors that operated last in 2004 (and will next be operated in 2007). From the 12 sites with SO2 data obtained between 2004 and 2006, 82,161 valid hourly averages were collected. A map of the active SO2 sampling sites is presented in Figure 5.14 and a detailed summary of the data from each site is given in Table 5.7. There were no exceedances of the SO2 ambient air quality standards in 2006. The highest annual arithmetic mean was 0.005 ppm, or about 17 percent of the standard (0.03 ppm). The highest maximum 24-hour average was 0.032 ppm, about 23 percent of the standard (0.14 ppm), and the highest maximum 3-hour average was 0.082 ppm, about 16 percent of the welfare-related (secondary) standard (0.50 ppm). Apparently, the size of an urban area has little effect on the ambient concentrations of SO2 in North Carolina. Seasonal variations, such as those with CO and O3, do not appear to exist for SO2. Major source characteristics such as type, size, distribution, control devices, operating conditions and dispersion situations significantly affect the amount of SO2 in ambient air. The second highest three-hour concentrations in each county are shown in Figure 5.15. The second highest 24-hour concentrations in each county are shown in Figure 5.16. 40 Figure 5.14 Locations of Sulfur Dioxide Monitoring Sites in 2004, 2005 and 2006 Table 5.7 Sulfur Dioxide in Parts Per Million from All Sites for 2004-2006 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA THREE-HOUR MAXIMA 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 1st 2nd 1st 2nd 2006 37-013-0006 NC 306@ PCS ENTRANCE 8,039 .041 .035 .027 .024 .009 .007 .0017 BEAUFORT AURORA 37-051-1003 3625 GOLFVIEW RD 8,262 .020 .019 .012 .011 .007 .007 .0022 CUMBERLAND HOPE MILLS 37-067-0022 1300 BLK. HATTIE AVE 7,240 .090 .082 .068 .049 .022 .020 .0052 FORSYTH WINSTON-SALEM 37-117-0001 MARTIN 1210 HAYES STREET JAMESVILLE 1,259 .015 .012 .009 .009 .006 .004 .0019 37-117-0002 MARTIN 33215 US HIGHWAY 64 536 .027 .020 .019 .017 .007 .005 .0022 37-119-0041 MECKLENBURG 1130 EASTWAY DRIVE CHARLOTTE 8,532 .083 .082 .071 .064 .017 .013 .0033 37-129-0006 HIGHWAY 421 NORTH 8,107 .173 .106 .082 .065 .032 .030 .0051 NEW HANOVER WILMINGTON 37-183-0014 WAKE 3801 SPRING FOREST RD. 7,813 .031 .027 .023 .020 .007 .006 .0015 RALEIGH Total Samples 49,788 Total Sites Sampled 8 41 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA THREE-HOUR MAXIMA 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 1st 2nd 1st 2nd 2005 37-129-0002 6028 HOLLY SHELTER RD 7,992 .067 .063 .037 .033 .009 .008 .0024 NEW HANOVER CASTLE HAYNE Total Samples 7,992 Total Sites Sampled 1 2004 DAT 37-065-0099 7589 NC HWY 33-NW 7,875 .018 .017 .016 .015 .009 .008 .0020 EDGECOMBE LEGGETT 37-145-0003 PERSON STATE ROAD 1102 & NC 49 8,276 .119 .096 .095 .073 .026 .021 .0039 ROXBORO 37-173-0002 SWAIN CENTER ST/PARKS & RECREATION FACILITY 8,230 .012 .012 .011 .010 .008 .006 .0021 BRYSON CITY Total Samples 24,381 Total Sites Sampled 3 42 Figure 5.15 Sulfur Dioxide: Second Highest 3-Hour Averages in the Most Recent Year of Data from 2004, 2005 or 2006 Figure 5.16 Sulfur Dioxide: Second Highest 24-Hour Averages in the Most Recent Year of Data from 2004, 2005 or 2006 43 5.7 Nitrogen Dioxide Nitrogen dioxide (NO2) concentrations were measured using EPA reference or equivalent continuous monitors in 2006 at one local program site in Forsyth County and one local program site in Mecklenburg County. From these two sites, 14,180 hourly NO2 measurements were reported. A map of the NO2 sampling sites is presented in Figure 5.17, and a summary of the 2006 NO2 data is given in Table 5.8. Each urban area site has only a few outlying high hourly sample values that are above the standard defined for the annual arithmetic mean. The arithmetic means (Table 5.8) are about 25 percent of the standard. Figure 5.17 Location of Nitrogen Dioxide Monitoring Sites Table 5.8 Nitrogen Dioxide in Parts Per Million for 2006 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA ARITH MEAN COUNTY 1ST 2ND 37-067-0022 1300 BLK. HATTIE AVENUE 7,142 0.054 0.053 0.011 FORSYTH WINSTON-SALEM 37-119-0041 1130 EASTWAY DRIVE 7,038 0.060 0.055 0.013 MECKLENBURG CHARLOTTE Total Samples 14,180 Total Sites Sampled 2 44 5.8 Lead The state and local program agencies have not performed routine analysis of ambient lead (Pb) in North Carolina since 1982. Lead monitoring was discontinued as a result of the low measurements and a continuing decrease in the lead concentrations being reported. The decrease in ambient Pb concentrations is due to the reduction and elimination of leaded gasoline, resulting in greatly reduced lead emissions from automobiles. 5.8.1 Special Studies The most recent year of data available prior to 1996-97 was in 1990. Because the previous data were so old, the state began metals analysis at three locations in 1996. These metal sites will be relocated to other locations in future years. The purpose of these sites is to gather background information about lead and other metals. No lead sites operated in 2006. The change in analytical laboratories from the EPA‟s National Particulate Analysis Program to the state program also changed the minimum detectable levels of the method from 0.01 to 0.04 g/m3, respectively. Concentrations of most metals are below detectable limits regardless of the method used. During 1999 and 2000, a special study focusing on arsenic levels was undertaken. Lead, and other toxic metals were sampled on filters using the TSP Reference Method at selected ambient air monitoring sites, by a contract laboratory using inductively coupled plasma/mass spectrometry (ICP/MS). This method can detect sample concentrations of lead as small as 0.01 nanograms (0.00001 g) per cubic meter. Of the 526 valid samples analyzed in 1999 only 18 exceeded the Reference Method‟s detection limits. Only one sample exceeded 0.04 g/m3, and 17 others exceeded 0.01 g/m3. 45 6 Air Quality Index The Air Quality Index (AQI) was developed by the EPA to provide the public with a simple, accessible, and uniform assessment of air quality at a specific location, based on the criteria pollutants PM2.5, PM10, CO, O3 (both 1 and 8 hour values), SO2 and NO2. AQI measurements are made and reported in all U.S. metropolitan statistical areas (MSA) with a population over 350,000. Ambient concentrations for each of these seven pollutants are converted to a numerical scale ranging from 0 to 500, where 100 corresponds to the EPA primary standard for a 24-hour average (8-hour CO average, 1 and 8-hour O3 average) and 500 corresponds to a concentration associated with significant harm. The AQI is determined by the pollutant with the highest scaled concentration, and a subjective description of good, moderate, “unhealthy for sensitive groups”, “unhealthy”, very unhealthy, or hazardous is included with the report, with the descriptions corresponding to AQI values of 0-50, 51-100, 101-150, 151-200, 201-300, and 301-500, respectively. For AQI values between 101 and 500, an appropriate cautionary statement is included advising people susceptible to deleterious health effects to restrict activities and exposure to the ambient air. An AQI of 101-200 (unhealthy for sensitive groups and unhealthy) can produce mild aggravation of symptoms in susceptible persons and possible irritation in healthy persons. People with existing heart or lung ailments should reduce physical exertion and outdoor activity. The general population should reduce vigorous outdoor activity. An AQI of 201 to 300 (very unhealthy) can produce significant aggravation of symptoms and decreased exercise tolerance in persons with heart or lung disease, and a variety of symptoms in healthy persons. Elderly people and those with existing heart or lung disease should stay indoors and reduce physical activity. The general population should avoid vigorous outdoor activity. The health effects of an AQI of over 300 (hazardous) include early onset of certain diseases in addition to significant aggravation of symptoms and decreased exercise tolerance in healthy persons. The elderly and persons with existing diseases should stay indoors and avoid physical exertion. At AQI values over 400, premature death of ill and elderly persons may result, and healthy people will experience adverse symptoms that affect normal activity. Outdoor activity should be avoided. All people should remain indoors, keeping windows and doors closed, and should minimize physical exertion. 46 During summer months in North Carolina the highest air quality index value tends to be attributed to ozone, but during winter months PM2.5 predominates, except where carbon monoxide monitors are operated. In 2006, Charlotte area provided an AQI report to the public by telephone using computer- generated recorded voice announcements 24 hours daily. The AQI report also may be published by local newspapers or broadcast on radio and television stations. The Air Quality Index report is available by telephone for Charlotte area at 704-333-SMOG. We also provide an AQI Report on the North Carolina DAQ web site, (http://www.daq.state.nc.us/monitor). In this printed report, we have summarized AQI statistics for six metropolitan areas in North Carolina. Table 6.1 shows the number of days in each health category at each area. In the Ashville MSA, the AQI was not “unhealthy for sensitive groups” or “unhealthy” for any days out of 364 days monitored. Figure 6.1 shows the 2006 AQI time series for Asheville. Figure 6.2 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Asheville. In the Charlotte-Gastonia-Rock Hill MSA, the AQI was “unhealthy for sensitive groups” or “unhealthy” on 20 out of 365 days monitored. All 20 of these days occurred between May and August. Figure 6.3 shows the 2006 AQI time series for Charlotte-Gastonia-Rock Hill. Figure 6.4 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Charlotte-Gastonia-Rock Hill. In the Fayetteville MSA, the AQI was not “unhealthy for sensitive groups” or “unhealthy” for any days out of 365 days monitored. Figure 6.5 shows the 2006 AQI time series for Fayetteville. Figure 6.6 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Fayetteville. In the Greensboro-Winston-Salem-High Point MSA, the AQI was “unhealthy for sensitive groups” or “unhealthy” on 11 out of 365 days monitored. All 11 of these days occurred between March and August. Figure 6.7 shows the 2006 AQI time series for Greensboro- Winston-Salem-High Point. Figure 6.8 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Greensboro-Winston-Salem-High Point. 47 In the Raleigh-Durham-Chapel Hill MSA, the AQI was “unhealthy for sensitive groups” or “unhealthy” on three out of 365 days monitored. All three of these days occurred between June and August. Figure 6.9 shows the 2006 AQI time series for Raleigh-Durham-Chapel Hill. Figure 6.10 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Raleigh-Durham-Chapel Hill. In the Wilmington MSA, the AQI was not “unhealthy for sensitive groups” or “unhealthy” for any days out of 364 days monitored. Figure 6.11 shows the 2006 AQI time series for Wilmington. Figure 6.12 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Wilmington. Table 6.1 Air Quality Index Category Days in the Major Metropolitan Statistical Areas, 2006 MSA STATISTICALTREATMENT GOOD MODERATE UNHEALTHY FOR SENSITIVE GROUPS UNHEALTHY Asheville actual 259 105 0 0 Charlotte actual 169 176 19 1 Fayetteville actual 242 123 0 0 Greensboro actual 174 180 10 1 Raleigh actual 199 163 3 0 Wilmington actual 310 54 0 0 48 Figure 6.1 Daily Air Quality Index Values for Asheville Figure 6.2 Daily Air Quality Index Summary for Asheville Days Per Main Pollutant 0 50 100 150 200 250 300 350 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 300 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 49 Figure 6.3 Daily Air Quality Index Values for Charlotte-Gastonia Figure 6.4 Daily Air Quality Index Summary for Charlotte-Gastonia Days Per Main Pollutant 0 50 100 150 200 250 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 20 40 60 80 100 120 140 160 180 200 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 50 Figure 6.5 Daily Air Quality Index Values for Fayetteville Figure 6.6 Daily Air Quality Index Summary for Fayetteville Days Per Main Pollutant 0 50 100 150 200 250 300 350 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 300 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 51 Figure 6.7 Daily Air Quality Index Values for Greensboro-Winston-Salem-High Point Figure 6.8 Daily Air Quality Index Summary for Greensboro-Winston-Salem-High Point Days Per Main Pollutant 0 50 100 150 200 250 300 350 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 20 40 60 80 100 120 140 160 180 200 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 52 Figure 6.9 Daily Air Quality Index Values for Raleigh-Durham-Chapel Hill Figure 6.10 Daily Air Quality Index Summary for Raleigh-Durham-Chapel Hill Days Per Main Pollutant 0 50 100 150 200 250 300 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 53 Figure 6.11 Daily Air Quality Index Values for Wilmington Figure 6.12 Daily Air Quality Index Summary for Wilmington Days Per Main Pollutant 0 50 100 150 200 250 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 300 350 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 54 7 Acid Rain 7.1 Sources Acid rain is produced when nitrate and sulfate ions from automobile and industrial sources are released into the atmosphere, undergo a reaction with moisture in the air, and are deposited as acid precipitation. Acid ions are produced when sulfur dioxide and nitrogen oxides react with water to form sulfuric acid and nitric acid. 7.2 Effects Many agricultural crops in North Carolina are sensitive to acid rain. Forests are subject to mineral loss from acid rain exposure and may also suffer root damage. Acid fogs and mists, typical in the mountains of North Carolina, can expose trees and plants to even higher acid concentrations and cause direct damage to foliage. Lakes, rivers and streams that are too acidic can impede fish and plant growth. 7.3 Monitoring Acid rain monitoring has been conducted nationally, including in North Carolina, since 1978 by the National Atmospheric Deposition Program (NADP) and the National Trends Network (NTN) which merged with NADP in 1982. In 2006, acid rain samples were collected at eight sites in North Carolina and one Tennessee site in the Great Smoky Mountains less than 10 miles from the western border of North Carolina. NADP conducts acid deposition monitoring using a wet/dry bucket type sampler. When rainfall is detected, a sensor is activated and a metal lid automatically covers and protects the dry sample, exposing the wet bucket to collect precipitation. Acidity is measured using a pH scale. The pH scale is numbered from 0 to 14, with 0 being extremely acidic and 14 being extremely basic. A substance with a pH of five is 10 times as acidic as one with a pH of six, 100 times as acidic as a substance with a pH of seven, etc. Neutral water with an equal concentration of acid and base ions has a pH of seven. The pH of vinegar is approximately 2.8, and lemon juice has a pH of about 2.3. The pH of ammonia is approximately 12. Pure water in equilibrium with the air is slightly acidic and has a pH of approximately 5.6. The measurements of pH at the North Carolina monitoring sites in 2006 ranged from 4.57 to 4.90 with a mean of 4.72. The 2006 pH annual means for North Carolina from the NADP database are presented in Figure 7.1 and Table 7.1. Table 7.1 also exhibits conductivity averages and precipitation totals for rainfall. Measured concentrations of several other chemical constituents of precipitation are given in Table 7.2. The highest pH (and the least acidic) precipitation occurred at the Sampson County site. This general area in southeastern North Carolina has the greatest numbers of animal producing farms. This 55 area has the highest emissions of ammonia, a basic gas emitted from animal wastes. Table 7.2 shows that the ammonium concentration in precipitation is the highest at the Sampson County site. Figure 7.1 Annual Mean pH Values at North Carolina NADP Sites, 2006 56 Table 7.1 pH, Conductivity in Microsiemans per Centimeter and Precipitation in Inches from the National Atmospheric Deposition Program for 2006. County Site ID Address pH Conductivity Precipitation Bertie NC03 Lewiston 4.75 11.98 54.52 Carteret NC06 Beaufort 4.72 17.61 50.20 Macon NC25 Coweeta 4.64 13.62 57.75 Rowan NC34 Piedmont Research Station 4.57 17.12 37.56 Sampson NC35 Clinton Crops Research Station 4.90 10.75 49.45 Scotland NC36 Jordan Creek 4.69 13.26 49.00 Wake NC41 Finley Farm 4.78 12.90 48.29 Yancey NC45 Mt. Mitchell 4.78 9.71 68.15 Sevier (TN) TN11 Great Smoky Mountains National Park-Elkmont 4.62 14.31 69.19 57 Table 7.2 Ion Concentrations in Milligrams per Liter (Precipitation-weighted Annual Means) from the National Atmospheric Deposition Program Data for 2006. County Site ID % Complete-ness Ca Mg K Na NH4 NO3 Cl SO4 Bertie NC03 90 0.067 0.023 0.026 0.155 0.240 0.686 0.285 1.095 Beaufort NC06 90 0.111 0.123 0.044 1.033 0.144 0.668 1.851 1.151 Macon NC25 92 0.073 0.017 0.023 0.111 0.177 0.666 0.204 1.288 Rowan NC34 96 0.112 0.025 0.084 0.112 0.346 0.958 0.243 1.722 Sampson NC35 98 0.062 0.023 0.018 0.175 0.367 0.679 0.329 1.102 Scotland NC36 92 0.082 0.025 0.021 0.167 0.237 .762 0.312 1.191 Wake NC41 96 0.082 0.021 0.042 0.118 0.415 0.805 0.233 1.385 Yancey NC45 19 0.055 0.007 0.014 0.015 0.165 0.465 0.035 0.958 Sevier (TN) TN11 88 0.106 0.016 0.031 0.047 0.247 0.814 0.091 1.421 58 8. Fine Particle Speciation 8.1 Description of pollutants The main species or constituents of fine particles are classified as nitrates, sulfates, ammonium, organic carbon, elemental carbon, and crustal components (dust). These account for 75 to 85 percent of the composition of fine particles. 8.1.1 Nitrate Ammonium nitrate (NH4NO3) is the most abundant nitrate compound, resulting from a reversible gas/particle equilibrium between ammonia gas (NH3), nitric acid gas (HNO3), and particulate ammonium nitrate. Sodium nitrate (NaNO3) is found in PM2.5 and PM10 near sea coasts and salt playas (e.g., Watson et al., 1995a) where nitric acid vapor irreversibly reacts with sea salt (NaCl). 8.1.2 Sulfate Ammonium sulfate ((NH4)2SO4), ammonium bisulfate (NH4HSO4), and sulfuric acid (H2SO4) are the most common forms of sulfate found in atmospheric particles, resulting from conversion of gases to particles as described below. These compound are water-soluble and reside almost exclusively in the PM2.5 size fraction. Sodium sulfate (Na2SO4) may be found in coastal areas where sulfuric acid has been neutralized by sodium chloride (NaCl) in sea salt. Though gypsum (Ca2SO4) and some other geological compounds contain sulfate, these are not easily dissolved in water for chemical analysis, are more abundant in PM10 than in PM2.5, and they are usually classified in the geological fraction. 8.1.3 Ammonium Ammonium sulfate ((NH4)2SO4), ammonium bisulfate (NH4HSO4), and ammonium nitrate (NH4NO3) are the most common compounds containing ammonium. 8.1.4 Organic Carbon Particulate organic carbon consists of hundreds, possibly thousands, of separate compounds with more than 20 carbon atoms. Because of this lack of molecular specificity and the semi-volatile nature of many carbon compounds with 20 to 40 carbon atoms, particulate “organic carbon” is operationally defined by the sampling and analysis method. 8.1.5 Elemental Carbon Elemental carbon is black, often called “soot.” Elemental carbon contains pure, graphitic carbon, but it also contains high molecular weight, dark-colored, non-volatile organic materials such as tar, biogenic, and coke. 59 8.1.6 Crustal Component (Fine Dust) Suspended dust consists mainly of oxides of aluminum, silicon, calcium, titanium, iron, lead and other metal oxides (Chow and Watson, 1998). The precise combination of these minerals depends on the geology of the area and industrial processes such as steel-making, smelting, mining, and cement production. Geological material is mostly in the coarse particle fraction, and typically constitutes about 50 percent of PM10 while only contributing 5 to 15 percent of PM2.5 (Chow and Watson, 1998). Lead is a toxic metal that was used for many years in products found in and around homes. Lead also is emitted into the air from motor vehicles and industrial sources. Lead may cause a range of health effects, from behavioral problems and learning disabilities, to seizures and death. The DAQ monitored lead as a federal criteria pollutant in the past (see chapter 5) until it become undetectable by the prescribed sampling method*. For these reasons we include concentration of the lead in PM2.5 in this report. 8.1.7 “Other” Speciated components. We categorize the 15 to 25 percent of PM2.5 not accounted for by nitrate, sulfate, ammonium, carbon and crustal components as “other” speciated data. For the purpose of this report “other” is not defined in any certain kind of particulate matter, but is simply the * EPA promulgated a new lead standard in 2008, and DAQ anticipates establishing a reporting network for it in 2011. result of subtracting all the other components from the total PM2.5 reported by the sampler. Among the constituents of “other” are liquid water and many trace chemical elements. 8.2 Sources Sources of fine particles include all types of combustion activities (motor vehicles, power plants, wood burning, etc.) and certain industrial processes. Other particles may be formed in the air from the chemical reactions of gases. They are indirectly formed when gases from burning fuels react with sunlight and water vapor. These can result from fuel combustion in motor vehicles, at power plants, and in other industrial processes. Particles emitted directly from a source may be either fine (less than 2.5 m) or larger (2.5 - 60 m), but particles photo-chemically formed in the atmosphere will usually be fine. Generally, larger particles have very slow settling velocities and are characterized as suspended particulate matter. Typically, fine particles originate by condensation of materials produced during combustion or atmospheric reactions. Fine particles also form from the reaction of gases or droplets in the atmosphere from sources such as power plants. These chemical reactions can occur miles from the original source of the emissions. Because fine particles can be carried long distances from their source, events such as wildfires or volcanic eruptions can raise fine particle concentrations hundreds of miles from the event. 60 PM2.5 is also produced by common indoor activities. Some indoor sources of fine particles are tobacco smoke, cooking (e.g., frying, sautéing, and broiling), burning candles or oil lamps, and operating fireplaces and fuel-burning space heaters (e.g., kerosene heaters). Particles and ozone are similar in many respects. Both can cause respiratory symptoms and other serious health problems. Fossil fuel combustion is a leading source of both pollutants. One significant difference is that particles can be a problem at any time of year, unlike ozone, which forms in warm, sunny weather and therefore tends to be seasonal in nature. 8.3 Effects The size of the particles is what is most important from a public health viewpoint. Particles larger than 10 m generally get caught in the nose and throat, never entering the lungs. Particles smaller than 10 m can get into the large upper branches just below your throat where they are caught and removed (by coughing and spitting or by swallowing). Particles smaller than 5 m can get into your bronchial tubes, at the top of the lungs; particles smaller than 2.5 m in diameter can get down into the deepest (alveolar) portions of your lungs where gas exchange occurs between the air and your blood stream, oxygen moving in and carbon dioxide moving out. These are the really dangerous particles because the deepest (alveolar) portions of the lung have no efficient mechanisms for removing them. If these particles are soluble in water, they pass directly into the blood stream within minutes. If they are not soluble in water, they are retained in the deep lung for long periods (months or years). About 60 percent of PM10 particles (by weight) have a diameter of 2.5 m or less. These are the particles that can enter the human lung directly. 8.4 Monitoring The MetOne SASS monitor measures PM2.5 mass and the chemical composition of PM2.5 (sulfates, nitrates, organic carbon, soot-like carbon and metals). This is known as PM2.5 chemical speciation. The MetOne SASS utilizes five independent channels (the Met One Super SASS utilizes eight independent channels) with spiral impactors attached directly to the filter cartridges that are arrayed in a raised carousel. Each canister has its own PM2.5 inlet and Federal Reference Method/Monitor filter holders. The PM2.5 separation is produced by a sharp cut cyclone that removes both solid and liquid coarse particles with equal efficiency without the use of impaction grease or oil. The Interagency Monitoring of Protected Visual Environments (IMPROVE) is a cooperation between federal land managers, state and local agencies and EPA to collect aerosol particulate data. IMPROVE sites use a different monitoring method. The standard IMPROVE sampler has four modules: (1) PM2.5 mass, (2) sulfate, nitrate and chloride, (3) PM2.5 quartz and (4) PM10 mass. Data are validated on a monthly basis when reports are received from the contract laboratory RTI International. NCDAQ collected data at ten sites using MetOne SASS method, the National Park Service collected at three sites during 2004 using the IMPROVE method. Figure 8.1 shows a map of all 61 these sites. Table 8.1 identifies the sites and the specific sampling methods employed at each one. Nitrate samples in 2006 are summarized in Table 8.2. The highest concentration observed was 5.71 g/m3 at Kinston. Sulfate samples in 2006 are summarized in Table 8.3. The highest concentration observed was 17.73 g/m3 at Linville. Ammonium samples in 2006 are summarized in Table 8.4. The highest concentration observed was 4.96 g/m3 at Greensboro. Organic Carbon samples in 2006 are summarized in Table 8.5. The highest concentration observed was 16.10 g/m3 at Rockwell. Elemental Carbon samples in 2006 are summarized in Table 8.6. The highest concentration observed was 3.68 g/m3 at Lexington. Crustal Component samples in 2006 are summarized in Table 8.7. The highest concentration observed was 10.20 g/m3 at Charlotte. Elemental lead samples for 2006 are summarized in Table 8.8. Out of 888 samples statewide, 34 samples exceeded 0.01 g/m3 ; 854 of these sample concentrations (96 percent) were less than 0.01 μg/m3. Twelve samples were greater than 0.014 g/m3. The highest concentration observed was 0.148 g/m3 at Lexington on Dec. 19, 2006. We were unable to find an explanation for this extremely unusual sample concentration. “Other” samples in 2006 are summarized in Table 8.9. The highest concentration observed was 70.12 g/m3 at Lexington. 62 Figure 8.1 Location of Nitrate, Sulfate, Ammonium, Organic Carbon, Elemental Carbon, Crustal component, “Other” component, Monitoring Sites 2006 Table 8.1 Fine Particle Speciation Sites Operated in North Carolina in 2006 SITE NUMBER ADDRESS METHOD COUNTY 37-011-0002 7510 BLUE RIDGE PARKWAY SPUR IMPROVE AVERY LINVILLE 37-021-0034 175 BINGHAM ROAD SASS BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET SASS CATAWBA HICKORY 37-057-0002 S.SALISBURY ST SASS DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE SASS FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD SASS GUILFORD GREENSBORO 37-087-0035 SHINING ROCK WILDERNESS IMPROVE HAYWOOD 63 SITE NUMBER ADDRESS METHOD COUNTY 37-095-9000 SWANQUARTER WILDLIFE REFUGE IMPROVE HYDE 37-107-0004 HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH SASS LENOIR KINSTON 37-119-0041 1130 EASTWAY DRIVE SASS MECKLENBURG CHARLOTTE 37-159-0021 301 WEST ST & GOLD HILL AVE SASS ROWAN ROCKWELL 37-183-0014 3801 SPRING FOREST RD SASS WAKE RALEIGH SITES OPERATED IN 12 2006 Table 8.2 Nitrate PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-011-0002 AVERY 7510 BLUE RIDGE PARKWAY SPUR 96 1.39 0.81 0.70 0.61 .209 LINVILLE 37-021-0034 175 BINGHAM ROAD 54 2.56 2.21 1.50 1.44 .625 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 5.22 3.88 3.21 2.70 .947 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 4.91 4.62 3.74 2.82 .988 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 5.28 3.23 3.16 2.42 .916 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 3.46 2.83 2.40 2.32 .729 GUILFORD GREENSBORO 37-087-0035 HAYWOOD TOWER BLUE RIDGE PARKWAY 110 1.09 0.93 0.88 0.85 .250 MILE MARKER 410 37-095-9000 SWANQUARTER 108 2.43 1.43 1.38 1.28 .386 HYDE 64 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 54 5.71 4.03 4.02 2.28 .989 KINSTON 37-119-0041 1130 EASTWAY DRIVE 118 5.59 4.70 3.63 2.67 .864 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 4.53 3.82 3.58 2.72 .873 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 5.38 2.96 2.76 2.62 1.007 WAKE RALEIGH Total Samples 893 Total Sites Sampled 12 Table 8.3 Sulfate PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-011-0002 AVERY 7510 BLUE RIDGE PARKWAY SPUR 96 17.73 15.61 12.27 10.44 4.002 LINVILLE 37-021-0034 175 BINGHAM ROAD 54 10.20 9.30 8.18 7.74 3.808 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 15.10 12.90 10.40 10.20 4.492 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 13.90 13.70 12.70 12.40 5.213 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 12.60 11.60 11.50 8.34 4.541 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 14.00 12.00 11.40 11.10 5.777 GUILFORD GREENSBORO 37-087-0035 HAYWOOD TOWER BLUE RIDGE PARKWAY 110 12.06 11.92 11.49 10.83 3.030 MILE MARKER 410 37-095-9000 SWANQUARTER 108 13.84 10.43 9.34 8.98 3.255 HYDE 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 54 10.80 8.54 7.91 7.53 3.805 KINSTON 65 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-119-0041 1130 EASTWAY DRIVE 118 14.80 12.80 11.40 11.30 4.397 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 12.10 10.90 10.70 10.60 4.722 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 9.02 9.00 7.78 7.05 3.603 WAKE RALEIGH Total Samples 893 Total Sites Sampled 12 Table 8.4 Ammonium Ion PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 2.91 2.88 2.86 2.39 1.232 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 4.35 4.13 3.83 3.80 1.653 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 4.40 4.11 3.90 3.86 1.852 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 4.29 3.84 3.69 3.39 1.716 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 4.96 3.94 3.29 3.19 1.904 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 54 4.40 4.15 3.26 3.15 1.515 KINSTON 37-119-0041 1130 EASTWAY DRIVE 118 4.13 4.09 3.73 3.58 1.550 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 4.09 3.92 3.70 3.45 1.649 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 4.04 3.57 3.09 2.95 1.448 WAKE RALEIGH Total Samples 579 Total Sites Sampled 9 66 Table 8.5 Organic Carbon CSN PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 15.70 9.04 8.61 7.61 4.649 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 11.00 10.50 10.00 8.90 5.649 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 12.60 12.30 10.70 9.29 5.635 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 10.30 9.05 8.96 7.80 4.613 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 45 10.30 9.11 7.70 7.30 4.741 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 56 8.69 7.66 5.72 6.57 3.676 KINSTON 37-119-0041 1130 EASTWAY DRIVE 115 11.50 10.00 9.57 9.51 4.962 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 16.10 10.30 9.67 8.81 5.102 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 9.21 8.58 8.15 7.45 4.556 WAKE RALEIGH Total Samples 580 Total Sites Sampled 9 Table 8.6 Elemental Carbon CSN PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 1.14 1.07 .96 .86 .502 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 2.41 2.27 2.09 1.69 .840 CATAWBA HICKORY 67 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-057-0002 S.SALISBURY ST 60 3.68 2.06 1.90 1.71 .759 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 2.11 1.62 1.58 1.53 .658 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 45 1.36 1.25 1.04 1.01 .545 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 56 1.01 .70 .69 .67 .317 KINSTON 37-119-0041 1130 EASTWAY DRIVE 115 2.79 1.91 1.90 1.84 .693 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 1.74 1.38 1.08 1.02 .554 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 1.77 1.69 1.68 1.60 .653 WAKE RALEIGH Total Samples 580 Total Sites Sampled 9 Table 8.7 Crustal Component PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 6.01 1.41 1.40 1.22 .537 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 56 1.04 .99 .98 .80 .421 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 59 3.91 1.27 1.26 1.04 .510 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 3.75 .82 .66 .65 .412 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 45 3.85 .81 .79 .78 .450 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 56 4.11 .98 .81 .79 .378 68 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th KINSTON 37-119-0041 1130 EASTWAY DRIVE 116 10.27 4.31 2.24 1.90 .608 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 3.66 1.02 .9
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Title | Ambient air quality report |
Date | 2010-11 |
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Full Text | 2006 Ambient Air Quality Report STATE OF NORTH CAROLINA Beverly Eaves Perdue, Governor DEPARTMENT OF ENVIRONMENT AND NATURAL RESOURCES Dee Freeman, Secretary DIVISION OF AIR QUALITY Sheila C. Holman, Director AMBIENT MONITORING SECTION Donald D. Redmond, Jr., Chief PUBLISHED November 2010 ii 2006 Ambient Air Quality Report Ambient Monitoring Section Report # 2010.03 Acknowledgements: Primary Author: Wayne Cornelius Additional Assistance: Lucyna Kozek Vitaly Karpusenko John Holland Public Sources of Data: North Carolina Division of Air Quality http://daq.state.nc.us/ Forsyth County Environmental Affairs Department http://www.co.forsyth.nc.us/EnvAffairs/weathereport.htm EPA/AQS Air Quality Subsystem http://www.epa.gov/airsweb National Atmospheric Deposition Program http://nadp.sws.uiuc.edu Published: November 2010 Not copyrighted. iii Preface This report is issued by the Division of Air Quality of the Department of Environment and Natural Resources to inform the public about air pollution levels throughout the state of North Carolina. It describes the sources and effects of the following pollutants for which the U.S. Environmental Protection Agency and the State of North Carolina have established ambient air quality standards: Particulate Matter Sulfur Dioxide Ozone Carbon Monoxide Nitrogen Dioxide Lead The report begins with a brief discussion of the ambient air monitoring program, including a description of the monitoring network. It presents detailed results of monitoring that was conducted in 2006 to measure the outdoor concentrations. The data are presented graphically and as statistical summaries, including comparisons to the ambient air quality standards. The report discusses the recorded data, and the seasonal variability of some pollutants. Data and areas exceeding the ambient air quality standards are identified. Factors that have contributed to those exceedances are also described. Acid rain data summaries from the National Atmospheric Deposition Program/National Trends Network for North Carolina also are included for 2006. Current air pollution information is available to the public 24 hours a day through the use of the air quality index telephone numbers listed below: Statewide toll-free 888-AIR-WISE (for Asheville, Charlotte, Fayetteville, Greenville, Hickory, Raleigh, Rocky Mount, Wilmington and Winston-Salem metro areas) Charlotte area 704-333-SMOG (for Mecklenburg County only) In 2002, the air monitoring program deployed a network of fine particle speciation monitors. This report provides data summaries from these monitors for 2006. Also in 2002, the Division of Air Quality established a small network of Urban Air Toxics monitors. It supplements a new national toxics database, and some key toxics pollutants are summarized for 2006 in this report. iv The report also contains graphical summaries of long-term annual trends for the criteria pollutants and acid rain data, highlighting successful efforts at pollution control and suggesting where future priorities should be placed. Additional copies of this report and previous annual reports are available on the Division of Air Quality‟s website http://daq.state.nc.us/monitor/reports/ or by writing to: Division of Air Quality 1641 Mail Service Center Raleigh, North Carolina 27699-1641 Comments regarding this report or suggestions for improving future reports are welcomed. Comments may be sent to Dr. Wayne L. Cornelius, at the above address. Sheila C. Holman, Director Division of Air Quality v Executive Summary In 2006, the North Carolina Division of Air Quality (DAQ), the three local program agencies and one tribal agency (listed in Appendix A) collected 305,161 air quality samples. These samples included measurements of the U.S. Environmental Protection Agency‟s (EPA) criteria air pollutants: particulate matter, carbon monoxide, ozone, sulfur dioxide, nitrogen dioxide and lead. This report discusses each pollutant and presents summary tables, maps, charts and explanations of the data. The report also includes data from weekly acid rain samples collected by the National Atmospheric Deposition Program (NADP) at seven North Carolina sites and one Tennessee site very close to the North Carolina border. It discusses acid rain and presents summary tables, maps, charts and explanations of the data. This report provides data summaries from a network of fine particle speciation monitors for 2006. The DAQ and two federal agencies deployed these monitors in 2002 to characterize more fully fine particulate matter by composition. This report presents a map and summary tables of the major speciation categories for 2006. Also in 2002, the Division of Air Quality established a small network of Urban Air Toxics monitors. It supplements a new national toxics database, and some key toxics pollutants are summarized for 2006 in this report. This report presents a map and summary tables of formaldehyde and five important volatile organic compounds for 2006. The report also contains graphical summaries of long-term annual trends for the criteria pollutants and acid rain data, highlighting successful efforts at pollution control and suggesting where future priorities should be placed. Three different types of particulate matter were sampled in North Carolina during 2006. Total Suspended Particulate (TSP), or particles having an aerodynamic diameter of 100 micrometers or less, is regulated by North Carolina standards. Particulate matter (PM10), with a mean aerodynamic diameter less than or equal to a nominal 10 micrometers (0.00004 inches), is regulated by both EPA and N.C. standards. Fine particulate matter (PM2.5), with a mean aerodynamic diameter less than or equal to a nominal 2.5 micrometers (0.00001 inches), has been regulated by EPA and NC since 1999. In 2006, TSP was sampled at seven sites, yielding 361 daily samples. There were no exceedances of the state TSP ambient air quality standard for 24-hour samples (150 g/m3) observed in 2006. PM10 was sampled at 15 sites, yielding 1,717 daily samples. There were no exceedances of the National Ambient Air Quality Standards for PM10 (150 g/m3 for 24-hour samples and 50 g/m3 for the annual arithmetic mean). vi PM2.5 was sampled at 35 sites yielding 5,176 daily samples. There were 17 exceedances of the ambient air quality standards for PM2.5 (35 g/m3 for 24-hour samples). Two of the 35 sites exceeded the annual arithmetic mean standard of 15 g/m3. Carbon monoxide (CO), largely results from fuel combustion. The most likely areas to have excessive CO concentrations are larger cities where there are more cars and congested streets. CO was sampled at five sites, yielding 28,259 valid hourly averages. The National Ambient Air Quality Standards for CO are 35 ppm for the maximum one-hour average and 9 ppm for the maximum eight-hour average. There were no exceedances of the standards. The highest one-hour concentration of 4.0 ppm was observed at the ABC Board in Cumberland County. The highest eight-hour concentration of 3.0 ppm was observed at the ABC Board in Cumberland County. The mean one-hour average has been decreasing by about 13 percent per year and the mean eight-hour average has been decreasing by about 15 percent per year. The combined effects of newer cars in the vehicle fleet, traffic control strategies, and the Inspection and Maintenance program in Cumberland, Durham, Orange, Wake, Forsyth, Guilford, Cabarrus, Gaston, Mecklenburg, and Union Counties have helped reduce the number and intensity of CO exceedances from previous years. Ozone (O3) forms in the lower atmosphere when hydrocarbons (or volatile organic compounds) and nitrogen oxides chemically react in the presence of sunlight and high temperatures. The main emphasis in control of ozone has been to limit hydrocarbon and nitrogen oxide emissions. O3 was sampled at 42 sites, yielding 205,680 valid hourly averages. The National Ambient Air Quality Standard for O3 in 2006 was 0.08 ppm for the maximum eight-hour average and 0.12 ppm for the maximum one-hour average. In 2006, there were no exceedances of the one-hour standard. Four exceedances occurred in North Carolina in 2005, and no exceedances occurred in 2004. Mecklenburg, Rowan and Wake Counties met or exceeded the criteria for attainment of the one-hour ozone standard with three, one and zero exceedances respectively over a three-year period. Mecklenburg County was redesignated as in attainment for ozone in July 1995. Hydrocarbon and NOx control strategies continue to be used there to help reduce ozone concentrations. In 2006, the 8-hour standard was exceeded 48 times, on 20 different days, with one county having eight exceedances at individual sites. The site at 29 N @ Mecklenburg Cab Co, Charlotte in Mecklenburg County had the highest number, eight. Sulfur dioxide (SO2) is mainly produced by combustion of fossil fuels containing sulfur compounds and the manufacture of sulfuric acid. SO2 was sampled at eight sites, yielding 49,788 valid hourly averages. There were no exceedances of the National Ambient Air Quality Standards (365 g/m3 or 0.14 ppm for a 24-hour average, 1300 g/m3 or 0.50 ppm for a three-hour average, 80 g/m3 or 0.03 ppm for the annual arithmetic mean) at network monitoring sites. vii Nitrogen oxides (NOx) are produced primarily from the burning of fossil fuels such as coal, oil and gasoline, due to the oxidation of atmospheric nitrogen and nitrogen compounds in the fuel. The primary combustion product is NO, which reacts with hydrocarbons, ozone and other atmospheric compounds to form NO2. NOx compounds play an important role in the formation of ozone. Reactive nitrogen species (NOy) were monitored in Charlotte and Winston-Salem to gather data for the development of control strategies for ozone non-attainment areas. The criteria pollutant NO2 was sampled at two sites, yielding 14,180 valid hourly averages. There were no exceedances of the National Ambient Air Quality Standard (0.053 ppm for the annual arithmetic mean). The mean one-hour average concentration has been decreasing by about 10 percent per year. Lead (Pb) emissions result from coal combustion and the sandblasting of highway bridges, overpasses, and water tanks. In the past, the combustion of gasoline containing tetraethyl lead as an additive was a major source. Lead was not sampled in 2006 using a Federal Reference Method. There have been no recent exceedances of the ambient air quality standard for lead (1.5 g/m3 for a quarterly arithmetic mean). From 1979 through 1999, mean lead concentrations have decreased by 92 percent. The steady decline in the use of leaded gasoline is primarily responsible for this trend. Acid Rain is produced when nitrate and sulfate ions from motor vehicles, combustion and industrial sources reach the upper atmosphere, react with moisture in the air, and are deposited as acid precipitation. Monitoring of pH and other ion concentrations in precipitation will help to identify trends and demonstrate the results of efforts to reduce emissions from mobile and industrial sources. The annual mean pH in 2006 ranged from 4.57 (Rowan County) to 4.90 (Sampson County). Speciated particulate samples were collected at 12 sites by the DAQ, two sites by the National Park Service and one site by the U.S. Forest Service. Categorizing these as nitrates, sulfates, ammonium, organic carbon, elemental carbon, crustal material, and “other” constitutents (liquid water, trace elements, etc.), there were 5,559 quantifiable concentrations 2006. By category, the highest concentrations of speciated particulate samples in 2006 were: sulfate 17.73 μg/m3; organic carbon 16.10 μg/m3; crustal component 6.01 μg/m3; nitrate 5.71 μg/m3; ammonium 4.96 μg/m3; elemental carbon 3.68 μg/m3; and other 70.12 μg/m3. Although there was no sampling for lead using a criteria pollutant method, the speciated particulate monitoring network provided 888 samples of PM2.5-lead in 2006; 854 of these sample concentrations (96 percent) were less than 0.01 μg/m3. Twelve samples exceeded 0.014 μg/m3. viii Urban Air Toxics sampling in 2006 occurred at seven sites, six urban and one rural. This effort contributes to the U.S. EPA‟s Air Toxics Monitoring Strategy by providing data to help assess health risks. The median concentrations of formaldehyde were 1.28-2.21 ppb at the urban sites and 1.50 ppb at the rural site. Median benzene concentrations were 0.27 to 0.37 ppb at the urban sites and 0.24 ppb at the rural site. Median toluene concentrations were 0.24 to 0.81 ppb at the urban sites and 0.17 ppb at the rural site. Median ethylbenzene concentrations were 0.05 to 0.14 ppb at the urban sites and 0.05 ppb at the rural site. Median m/p-xylene concentrations were 0.09 to 0.46 ppb at the urban sites and 0.05 ppb at the rural site. Median o-xylene concentrations were 0.05 to 0.14 ppb at the urban sites and 0.05 at the rural site. Median 1, 3-butadiene concentrations were 0.05 ppb at the urban sites and at the rural site. Ambient Trends: Annual average statewide concentrations of PM10 decreased by 29 percent from 1989 to 2006. Annual average statewide concentrations of CO (as 8-hour averages) have decreased by 49 percent from 1995 to 2006. Annual average highest 8-hour ozone concentrations decreased by 12 percent from 1990 to 2006. Annual average highest 3-hour sulfur dioxide concentrations decreased by 63 percent from 1989 to 2006, and annual average of annual means decreased by 58 percent in the same time period. Annual average nitrogen dioxide concentrations remained constant from 1989 to 2006 in Forsyth County and Mecklenburg County, the only locations where this pollutant is monitored at present. Acid Rain Trends: Annual average pH in rain increased about 4 percent from 1991 to 2006. Annual average ammonium concentrations increased about 29 percent from 1991 to 2006, but this was dominated by very significant increases in Sampson County associated with concentrated livestock animal production. Annual average nitrate concentrations in rain decreased about 21 percent from 1991 to 2006. Annual average sulfate concentrations in rain decreased about 19 percent from 1991 to 2006. ix CONTENTS 1 Introduction ................................................................................................................................ 1 2 Descriptions of Criteria Pollutants .............................................................................................. 2 2.1 Particulate Matter ..................................................................................................................... 2 2.1.1 Sources ............................................................................................................................... 2 2.1.2 Effects ................................................................................................................................ 2 2.2 Carbon Monoxide .................................................................................................................... 3 2.2.1 Sources ............................................................................................................................... 3 2.1.2 Effects ................................................................................................................................ 3 2.3 Ozone ...................................................................................................................................... 3 2.3.1 Sources ............................................................................................................................... 4 2.3.2 Effects ................................................................................................................................ 4 2.4 Sulfur Dioxide ......................................................................................................................... 4 2.4.1 Sources ............................................................................................................................... 4 2.4.2 Effects ................................................................................................................................ 4 2.5 Nitrogen Oxides ...................................................................................................................... 5 2.5.1 Sources ............................................................................................................................... 5 2.5.2 Effects ................................................................................................................................ 5 2.6 Lead........................................................................................................................................ 5 2.6.1 Sources ............................................................................................................................... 5 2.6.2 Effects ................................................................................................................................ 6 3 Standards .................................................................................................................................. 7 4 Ambient Air Quality Monitoring Program ............................................................................... 9 5 Pollutant Monitoring Results .................................................................................................. 16 5.1 Total Suspended Particulates ................................................................................................ 16 5.2 PM10 ..................................................................................................................................... 18 5.3 Fine Particulate Matter, (PM2.5) ............................................................................................ 20 5.4 Carbon Monoxide ................................................................................................................. 27 5.5 Ozone .................................................................................................................................. 30 5.6 Sulfur Dioxide ...................................................................................................................... 39 5.7 Nitrogen Dioxide ................................................................................................................. 43 5.8 Lead..................................................................................................................................... 44 5.8.1 Special Studies .................................................................................................................... 44 6 Air Quality Index .................................................................................................................. 45 7 Acid Rain .............................................................................................................................. 53 7.1 Sources .............................................................................................................................. 54 7.2 Effects ............................................................................................................................... 54 7.3 Monitoring ............................................................................................................................ 54 8. Fine Particle Speciation ........................................................................................................ 58 8.1 Description of Pollutants...................................................................................................... 58 8.1.1 Nitrate ............................................................................................................................... 58 8.1.2 Sulfate ............................................................................................................................... 58 8.1.3 Ammonium ....................................................................................................................... 58 8.1.4 Organic Carbon ................................................................................................................. 58 8.1.5 Elemental Carbon.............................................................................................................. 58 x 8.1.6 Crustal Component (Fine Dust) ........................................................................................ 59 8.1.7 “Other” Speciated Components. ........................................................................................ 59 8.2 Sources .............................................................................................................................. 59 8.3 Effects ............................................................................................................................... 60 8.4 Monitoring ........................................................................................................................ 60 9. Urban Air Toxics ..................................................................................................................... 70 9.1 Sources .............................................................................................................................. 70 9.2 Effects ............................................................................................................................... 70 9.3 Formaldehyde ....................................................................................................................... 71 9.3.1 Sources .............................................................................................................................. 71 9.3.2 Effects ............................................................................................................................... 71 9.4 Benzene ................................................................................................................................ 71 9.4.1 Sources .............................................................................................................................. 71 9.4.2 Effects ............................................................................................................................... 71 9.5 Toluene ................................................................................................................................ 72 9.5.1 Sources .............................................................................................................................. 72 9.5.2 Effects ............................................................................................................................... 72 9.6 Ethylbenzene .......................................................................................................................... 72 9.6.1 Sources .............................................................................................................................. 72 9.6.2 Effects ............................................................................................................................... 73 9.7 Xylene ................................................................................................................................... 73 9.7.1 Sources .............................................................................................................................. 73 9.7.2 Effects ............................................................................................................................... 73 9.8 1,3 Butadiene ......................................................................................................................... 73 9.8.1 Sources .............................................................................................................................. 73 9.8.2 Effects ............................................................................................................................... 74 9.9 Monitoring 2006 ................................................................................................................... 74 10 Statewide Trends .................................................................................................................. 81 10.1 Particulate Matter ................................................................................................................. 81 10.2 Carbon Monoxide ................................................................................................................ 81 10.3 Ozone .................................................................................................................................. 81 10.4 Sulfur Dioxide ..................................................................................................................... 81 10.5 Nitrogen Dioxide ................................................................................................................. 82 10.6 pH ........................................................................................................................................ 82 10.7 Ammonium Ion .................................................................................................................... 82 10.8 Nitrate Ion ............................................................................................................................ 82 10.9 Sulfate Ion ............................................................................................................................ 83 Appendix A. Air Pollution Monitoring Agencies ......................................................................... 90 Appendix B. Exceptional Events .................................................................................................. 93 Appendix C. Box-And-Whisker Plots .......................................................................................... 94 Appendix D. Nonattainment and North Carolina ......................................................................... 95 xi List of Tables Table 3.1 National and North Carolina Ambient Air Quality Standards ........................................ 8 Table 4.1 Ambient Air Monitoring Sites Operated in North Carolina, 2006 ............................... 11 Table 5.1 Total Suspended Particulates in Micrograms Per Cubic Meter for 2006 ..................... 17 Table 5.2 PM10 in Micrograms Per Cubic Meter for 2006 ........................................................... 19 Table 5.3 PM2.5 in Micrograms Per Cubic Meter for 2006........................................................... 22 Table 5.4 Carbon Monoxide in Parts Per Million for 2006 .......................................................... 28 Table 5.5 One-Hour Ozone in Parts Per Million for 2006 ........................................................... 31 Table 5.6 Eight-Hour Ozone in Parts Per Million for 2006 .......................................................... 35 Table 5.7 Sulfur Dioxide in Parts Per Million from All Sites for 2004-2006 .............................. 40 Table 5.8 Nitrogen Dioxide in Parts Per Million for 2006 ........................................................... 43 Table 6.1 Air Quality Index Category Days in the Major Metropolitan Statistical Areas, 2006 . 47 Table 7.1 pH, Conductivity in Microsiemans per Centimeter and Precipitation in Inches from the National Atmospheric Deposition Program for 2006 ........................................................... 56 Table 7.2 Ion Concentrations in Milligrams per Liter (Precipitation-weighted Annual Means) from the National Atmospheric Deposition Program Data for 2006 .................................... 57 Table 8.1 Fine Particles Speciation Sites Operated in North Carolina in 2006 ............................ 62 Table 8.2 Nitrate PM2.5- Micrograms/Cubic Meter (LC) for 2006 ............................................... 63 Table 8.3 Sulfate PM2.5- Micrograms/Cubic Meter (LC) for 2006 .............................................. 64 Table 8.4 Ammonium Ion PM2.5- Micrograms/Cubic Meter (LC) for 2006 ................................ 65 Table 8.5 Organic Carbon CSN PM2.5- Micrograms/Cubic Meter (LC) for 2006 ....................... 66 Table 8.6 Elemental Carbon CSN PM2.5- Micrograms/Cubic Meter (LC) for 2006 .................... 66 Table 8.7 Crustal Component PM2.5- Micrograms/Cubic Meter (LC) for 2006........................... 67 Table 8.8 Lead PM2.5- Micrograms/Cubic Meter (LC) for 2006 .................................................. 68 Table 8.9 “Other” Component PM2.5- Micrograms/Cubic Meter (LC) for 2006 ......................... 69 Table 9.1 Formaldehyde - Parts per billion for 2006 .................................................................... 76 Table 9.2 Benzene - Parts per billion for 2006 ............................................................................. 77 Table 9.3 Toluene - Parts per billion for 2006 .............................................................................. 77 Table 9.4 Ethylbenzene - Parts per billion for 2006 ..................................................................... 78 Table 9.5 m/p-Xylene - Parts per billion for 2006 ........................................................................ 79 Table 9.6 o-Xylene -Parts per billion for 2006 ............................................................................. 79 Table 9.7 1,3-Butadiene ................................................................................................................ 80 xii List of Figures Figure 4.1 Monitoring Sites Active in 2006 ................................................................................. 10 Figure 5.1 Location of PM10 Monitoring Sites ............................................................................. 18 Figure 5.2 PM10: Second Highest 24-Hour Averages, 2006 ........................................................ 20 Figure 5.3 PM10: Maximum Annual Arithmetic Means, 2006 .................................................... 20 Figure 5.4 Location of PM2.5 Monitoring Sites ............................................................................ 22 Figure 5.5 PM2.5: 98th percentile, 2006 ........................................................................................ 25 Figure 5.6 PM2.5: Annual Arithmetic Means, 2006 ..................................................................... 25 Figure 5.7 PM2.5: Design Values by County, 2004-2006 ............................................................ 26 Figure 5.8 Location of Carbon Monoxide Monitoring Sites ........................................................ 28 Figure 5.9 Carbon Monoxide: Second Highest 1-Hour Concentration, 2006 .............................. 29 Figure 5.10 Carbon Monoxide: Second Highest Non-overlapping 8-Hour Concentration, 2006 29 Figure 5.11 Location of Ozone Monitoring Sites ......................................................................... 31 Figure 5.12 Ozone: Second Highest Annual 1-Hour Average, 2006 ........................................... 38 Figure 5.13 Ozone: Mean Annual Fourth Highest 8-Hour Average, 2004-2006 ........................ 38 Figure 5.14 Locations of Sulfur Dioxide Monitoring Sites in 2004, 2005 and 2006 ................... 40 Figure 5.15 Sulfur Dioxide: Second Highest 3-Hour Averages in the Most recent Year of Data from 2004, 2005 and 2006 .................................................................................................... 42 Figure 5.16 Sulfur Dioxide: Second Highest 24-Hour Averages in the Most Recent Year of Data from 2004, 2005 or 2006 ...................................................................................................... 42 Figure 5.17 Location of Nitrogen Dioxide Monitoring Sites ...................................................... 43 Figure 6.1 Daily Air Quality Index Values for Asheville ............................................................ 48 Figure 6.2 Daily Air Quality Index Summary for Asheville ........................................................ 48 Figure 6.3 Daily Air Quality Index Values for Charlotte-Gastonia .............................................. 49 Figure 6.4 Daily Air Quality Index Summary for Charlotte-Gastonia ......................................... 49 Figure 6.5 Daily Air Quality Index Values for Fayetteville ......................................................... 50 Figure 6.6 Daily Air Quality Index Summary for Fayetteville ..................................................... 50 Figure 6.7 Daily Air Quality Index Values Greensboro-Winston-Salem-High Point .................. 51 Figure 6.8 Daily Air Quality Index Summary Greensboro-Winston-Salem-High Point .............. 51 Figure 6.9 Daily Air Quality Index Values for Raleigh-Durham- Chapel Hill ............................ 52 Figure 6.10 Daily Air Quality Index Summary for Raleigh-Durham-Chapel Hill ....................... 52 Figure 6.11 Daily Air Quality Index Values for Wilmington ....................................................... 53 Figure 6.12 Daily Air Quality Index Summary for Wilmington .................................................. 53 Figure 7.1 Annual Mean pH Values at North Carolina NADP Sites, 2006.................................. 55 Figure 8.1 Location of Nitrate, Sulfate, Ammonium, Organic Carbon, Elemental Carbon, Crustal component, "Other" component, Monitoring Sites 2006 ...................................................... 62 Figure 9.1 Location Urban Air Toxics Monitoring Sites 2006 ..................................................... 76 Figure 10.1 Distribution of Statewide Second-Maximum 24-Hour PM10 Concentrations, 1989- 2006, and Smoothed Regression Trend Line ....................................................................... 83 xiii Figure 10.2 Distribution of Statewide Second-Maximum 8-Hour Carbon Monoxide Concentrations, 1994-2006, and Smoothed Regression Trend Line ................................... 84 Figure 10.3 Distribution of Statewide Fourth-Maximum 8-Hour Ozone Concentrations, 1990- 2006, and Smoothed Regression Trend Line ....................................................................... 84 Figure 10.4 Number of Days with Exceedances of 8-Hour Ozone Averages of 0.085 ppm or Greater, 1990-2006 ............................................................................................................ 85 Figure 10.5 Distribution of Statewide Second-Maximum 3-Hour Sulfur Dioxide Concentrations, 1989- 2006, and Smoothed Regression Trend Line ............................................................ 85 Figure 10.6 Distribution of Statewide Second- Maximum 24-Hour Sulfur Dioxide Concentrations, 1989- 2006, and Smoothed Regression Trend Line ................................. 86 Figure 10.7 Distributions of Forsyth and Mecklenburg County Annual Mean Nitrogen Dioxide Concentrations, 1989- 2006, and Smoothed Regression Trend Line .................................. 86 Figure 10.8 Distribution of Statewide Annual Mean pH, 1991- 2006.......................................... 87 Figure 10.9 Distribution of Statewide Annual Mean Ammonium Ion Concentrations, 1991- 2006 .......................................................................................................................... 87 Figure 10.10 Distribution of Statewide Annual Mean Nitrate Ion Concentrations, 1991- 2006, and Smoothed Regression Trend Line ................................................................................. 88 Figure 10.11 Distribution of Statewide Annual Mean Sulfate Ion Concentrations, 1991- 2006, and Smoothed Regression Trend Line .................................................................................. 88 1 1. Introduction This annual report summarizes the ambient air monitoring performed in calendar year 2006 by the North Carolina Division of Air Quality (DAQ), three local air pollution agencies and one tribal agency, which are more fully described in Appendix A. These agencies collected 305,161 air quality samples of the U.S. Environmental Protection Agency‟s (EPA) criteria pollutants (particulate matter, carbon monoxide, ozone, sulfur dioxide, nitrogen dioxide and lead), which are discussed in this report. Chapter 2 describes the criteria pollutants and discusses their sources and effects on human health, plants and animals. Chapter 3 outlines the standards applied to criteria pollutant concentrations established by the EPA and the state of North Carolina to protect human health (primary standards) and plants, animals, and property (secondary standards). Chapter 4 describes the ambient monitoring program conducted by DAQ and three local program agencies. Chapter 5 gives detailed monitoring results for each pollutant, with a map of the monitor sites, a table of the monitor summary statistics relevant to the standards, one or more maps summarizing the important statistics for each county with monitors, and additional summaries as appropriate to each pollutant. Chapter 6 describes the EPA Air Quality Index for the criteria pollutants and charts index measurements for five Metropolitan Statistical Areas of North Carolina. Chapter 7 presents sources, effects and monitoring of acid rain data conducted in North Carolina by the National Atmospheric Deposition Program and National Trends Network (NADP). It also includes a map of the calendar year mean pH level and site statistics for the calendar year in two tables. Chapter 8 describes a small network of fine particulate speciation compounds that DAQ initiated in 2002. The chapter contains annual summaries of seven main components of fine particles. We also report summary of lead here (instead of chapter 5). Chapter 9 describes the Urban Air Toxics monitoring program in North Carolina. The DAQ and local air pollution agencies sampled volatile organic compounds at seven sites. This chapter contains annual summaries for five important toxic pollutants. Chapter 10 provides a statewide summary of trends for the criteria pollutants from 1989 and 1991 (1994 for CO and 1990 for O3) through 2006. 2 2 Descriptions of Criteria Pollutants 2.1 Particulate Matter Atmospheric particulate matter is defined as any airborne material, except uncombined water (liquid, mist, steam, etc.), that exists in a finely divided form as a liquid or solid at standard temperature (25° C) and pressure (760 mm mercury) and has an aerodynamic diameter of less than 100 micrometers (m). In the period covered by this report, three sizes of particulate matter were monitored, total suspended particulate (TSP), PM10 and PM2.5. TSP is any particulate matter measured by the method described in EPA regulations 40 CFR 50 App. B (United States Environmental Protection Agency [US EPA] 1993, p. 715-728) and is generally considered to be particles having an aerodynamic diameter of 40 m or less (Watson and Chow 2001), although particles up to about 100 m are sometimes captured by samplers. (The probability of inhalation for 100 m particles is about 50 percent and increases with decreasing particle size [Maynard and Jensen 2001].) PM10 is particulate matter with an aerodynamic diameter less than or equal to 10 m as measured according to EPA regulations 40 CFR 50 App. J (US EPA 1993, p. 769-773). TSP measurements have been made in North Carolina since the early 1960s, and PM10 has been sampled locally in Charlotte since 1985 and statewide since 1986 (North Carolina Department of Environment, Health, and Natural Resources 1991a). The PM2.5 standard was adopted by North Carolina on April 1, 1999. On May 14, 1999, the U.S. Court of Appeals ruled the setting of the standard by EPA was an unconstitutional use of authority and could be vacated. The Supreme Court later upheld the new standard. EPA continues to require monitoring for PM2.5. 2.1.1 Sources Particulates are emitted by many human activities, such as fuel combustion, motor vehicle operation, industrial processes, grass mowing, agricultural tilling and open burning. Natural sources include windblown dust, forest fires, volcanic eruptions, and plant pollen. Particles emitted directly from a source may be either fine (less than 2.5 m) or larger (2.5 - 60 m), but particles photo-chemically formed in the atmosphere will usually be fine. Generally, larger particles have very slow settling velocities and are characterized as suspended particulate matter. Typically, fine particles originate from condensation of materials produced during combustion or atmospheric reactions. 2.1.2 Effects Particulate matter can cause health problems affecting the breathing system, including aggravation of existing lung and heart disease, limitation of lung clearance, changes in form and structure of organs, and development of cancer. Individuals most 3 sensitive to the effects of particulate matter include those with chronic obstructive lung or heart disease, those suffering from the flu, asthmatics, the elderly, children, and mouth breathers. Health effects from inhaled particles are influenced by the depth of penetration of the particles into the respiratory system, the amount of particles deposited in the respiratory system, and by the biological reaction to the deposited particles. The risks of adverse health effects are greater when particles enter the tracheobronchial and alveolar portions of the respiratory system. Small particles can penetrate into these deeper regions of the respiratory system. Healthy respiratory systems can trap particles larger than 10 micrometers more efficiently before they move deeply into the system and can more effectively remove the particles that are not trapped before deep movement. Particulate matter also can interfere with plant photosynthesis, by forming a film on leaves reducing exposure to sunlight. Particles also can cause soiling and degradation of property, which can be costly to clean and maintain. Suspended particles can absorb and scatter light, causing reduction of visibility. This is a national concern, especially in areas such as national parks, historic sites and scenic attractions visited by sightseers. 2.2 Carbon Monoxide Carbon monoxide (CO) is the most commonly occurring air pollutant. CO is a colorless and poisonous gas produced by incomplete burning of carbon-containing fuel. 2.2.1 Sources Most atmospheric CO is produced by incomplete combustion of fuels used for vehicles, space heating, industrial processes and solid waste incineration. Transportation accounts for the majority of CO emissions. Boilers and other fuel burning heating systems are also significant sources. 2.1.2 Effects Breathing carbon monoxide affects the oxygen-carrying capacity of the blood. Hemoglobin in the blood binds with CO more readily than with oxygen, starving the body of vital oxygen. Individuals with anemia, lung and heart diseases are particularly sensitive to CO effects. Low concentrations affect mental function, vision and alertness. High concentrations can cause fatigue, reduced work capacity and may adversely affect fetal development. Chronic exposure to CO at concentrations as low as 70 ppm (80 mg/m3) can cause cardiac damage. Other health effects associated with exposure to CO include central nervous system effects and pulmonary function difficulties. Ambient CO apparently does not adversely affect vegetation or materials. 2.3 Ozone Ozone is a clear gas that forms in the troposphere (lower atmosphere) by chemical reactions involving hydrocarbons (or volatile organic compounds) and nitrogen oxides in the presence of sunlight and high temperatures. Even low concentrations of 4 tropospheric ozone are harmful to people, animals, vegetation and materials. Ozone is the most widespread and serious criteria air pollutant in North Carolina. Ozone in the upper atmosphere (stratosphere) shields the earth from harmful effects of ultraviolet solar radiation. Stratospheric ozone can be damaged by the emission of chlorofluoro hydrocarbons (CFCs) such as Freon. 2.3.1 Sources Ozone (O3) is the major component of a complex mixture of compounds known as photochemical oxidants. Ozone is not usually emitted directly into the atmosphere, but is formed by a series of complex reactions involving hydrocarbons, nitrogen oxides and sunlight. Ozone concentrations are higher during the daytime in late spring, summer and early autumn when the temperature is above 60º F and the sunlight is more intense. Two natural sources of upper atmosphere ozone are solar radiation and lightning during thunderstorms. These are not significant sources of tropospheric (ground level) ozone. 2.3.2 Effects Ozone is a pulmonary irritant, affecting the respiratory mucous membranes, as well as other lung tissues and respiratory functions. Ozone has been shown to impair normal function of the lung causing shallow, rapid breathing and a decrease in pulmonary function. Other symptoms of exposure include chest tightness, coughing and wheezing. People with asthma, bronchitis or emphysema probably will experience breathing difficulty when exposed to short-term concentrations between 0.15 and 0.25 ppm. Continued or repeated long-term exposure may result in permanent lung structure damage. Ozone damages vegetation by injuring leaves. Ozone also accelerates material aging by cracking rubber, fading dyes and eroding paint. 2.4 Sulfur Dioxide Sulfur dioxide (SO2) is a colorless, corrosive, harmful gas with a pungent odor. Smaller concentrations of sulfur trioxide and other sulfate compounds are also found in SO2 emissions. Sulfur oxides contribute to the formation of acid rain and the formation of particles that reduce visibility. 2.4.1 Sources The main sources of SO2 are combustion of fossil fuels containing sulfur compounds and the manufacture of sulfuric acid. Other sources include refining of petroleum and smelting of ores that contain sulfur. 2.4.2 Effects The most obvious health effect of sulfur dioxide is irritation and inflammation of body tissues brought in contact with the gas. Sulfur dioxide can increase the severity of existing respiratory diseases such as asthma, bronchitis, and emphysema. Sulfuric acid and fine particulate sulfates, which are formed from sulfur dioxide, also may cause significant health problems. Sulfur dioxide causes injury to many plants. A bleached 5 appearance between the veins and margins on leaves indicates damage from SO2 exposure. Commercially important plants sensitive to SO2 include cotton, sweet potatoes, cucumber, alfalfa, tulips, apple trees, and several species of pine trees. 2.5 Nitrogen Oxides Several gaseous oxides of nitrogen are normally found in the atmosphere, including nitrous oxide (N2O), nitric oxide (NO) and nitrogen dioxide (NO2). Nitrous oxide is a stable gas with anesthetic characteristics and typical ambient concentrations well below the threshold concentration for a biological effect. Nitric oxide is a colorless gas with ambient concentrations generally low enough to have no significant biological effect. Nitrogen dioxide is reddish-brown but is not usually visible at typical ambient concentrations. 2.5.1 Sources The most significant nitrogen oxide emissions result from the burning of fossil fuels such as coal, oil and gasoline, due to the oxidation of atmospheric nitrogen and nitrogen compounds in the fuel. The primary combustion product is NO, which reacts to form NO2. 2.5.2 Effects At typical concentrations, nitrogen dioxide has significant health effects as a pulmonary irritant, especially upon asthmatics and children. In North Carolina, a much greater health concern is the formation of ozone, which is promoted by the presence of NO2 and other nitrogen oxides. Some types of vegetation are very sensitive to NO2, including oats, alfalfa, tobacco, peas and carrots. Chronic exposure causes chlorosis (yellowing) and acute exposure usually causes irregularly shaped lesions on the leaves. Nitric oxide and nitrogen dioxide do not directly damage materials. However, NO2 can react with moisture in the air to produce nitric acid, which corrodes metal surfaces and contributes to acid rain. High concentrations of NO2 may reduce visibility. Much of the brownish coloration sometimes observed in polluted air in winter months may be due to NO2. 2.6 Lead Lead is a toxic heavy metal element occurring in the atmosphere as small particles. 2.6.1 Sources The major source of atmospheric lead used to be the combustion of gasoline containing the additive tetraethyl lead as an anti-knock agent. However, the availability of leaded fuel has declined, and the concentration of lead in such fuel has decreased, minimizing gasoline as a source. Significant remaining sources include coal combustion (lead exists in very small quantities as an impurity in coal) and sandblasting of highway structures and water tanks. Lead also is used in some batteries, paints, insecticides, newspaper inks and piston engine aircraft gasoline. 6 2.6.2 Effects Lead (Pb) persists and accumulates in the environment and the human body. It may be inhaled, ingested, and eventually absorbed into the bloodstream and distributed to all body tissues. Exposure to low concentrations interferes with blood production and specific enzyme systems. It is believed to cause kidney and nerve cell damage, and severe lead poisoning is known to cause brain damage in children. 7 3 Standards Ambient air quality status is determined by measuring pollutant concentrations in outdoor air and comparing the measured concentrations to corresponding standards. The US EPA (Environmental Protection Agency) defines the ambient air as “that portion of the atmosphere, external to buildings, to which the general public has access.” Ambient air quality standards are classified as primary and secondary. Primary standards are those established to protect public health. Secondary standards are those established to protect the public welfare from adverse pollution effects on soils, water, crops, vegetation, man-made materials, animals, wildlife, weather, visibility, climate, property, transportation, economy, and personal comfort and well-being. The scientific criteria upon which the standards are based are reviewed periodically by the EPA, which may reestablish or change the standards according to its findings. A pollutant measurement that is greater than the ambient air quality standard for a specific averaging time is called an exceedance. The national primary, secondary and North Carolina ambient air quality standards that were in effect during 2006 are summarized in Table 3.1. 8 Table 3.1 National and North Carolina Ambient Air Quality Standards For new or anticipated new standards, References in the Code of Federal Regulations are given. For standards expressed in parts per million, an equivalent mass per unit volume is also shown. Pollutant/ Ambient Measurement/ (Reference) Averaging Period Type of Summary Primary National (Health Related) Standard Secondary National (Welfare Related) Standard North Carolina Standard TSP 24 hour average 1 year geometric mean (1) (1) 75 μg/m3 1 day 2nd maximum (1) (1) 150 μg/m3 PM-2.5 24 hour average (40CFR50, App. N) 1 year average2 arithmetic mean 15 μg/m3 (6) 15 μg/m3 (6) 15 μg/m3 (6) 1 day average2 98th percentile 35 μg/m3 (7) 35 μg/m3 35 μg/m3 (6) PM-10 24 hour average (40CFR50, App. N) 1 year average2 arithmetic mean 50 μg/m3 50 μg/m3 50 μg/m3 1 day average2 2nd maximum3 150 μg/m3 150 μg/m3 150 μg/m3 CO 1 hour average 8 hours 2nd maximum 9 ppm (10 mg/m3) 9 ppm (10 mg/m3) 1 hour 2nd maximum 35 ppm (40 mg/m3) 35 ppm (40 mg/m3) O3 1 hour average (40CFR50, App. I) 1 hour expected4 2nd maximum 0.12 ppm (6) (235 μg/m3) 0.12 ppm (6) (235 ��g/m3) 0.12 ppm (235 μg/m3) (6,8) 8 hours average5 arithmetic mean 4th maximum 0.08 ppm (6) (157 μg/m3) 0.08 ppm (6) (157 μg/m3) 0.08 ppm (6) (157 μg/m3) SO2 1 hour average 1 year arithmetic mean 0.03 ppm (80 μg/m3) 0.03 ppm (80 μg/m3) 1 day 2nd maximum 0.14 ppm (365 μg/m3) 0.14 ppm (365 μg/m3) 3 hours (non-overlapping) 2nd maximum 0.50 ppm (1,300 μg/m3) 0.50 ppm (1,300 μg/m3) NO2 1 hour average 1 year arithmetic mean 0.053 ppm (100 μg/m3) 0.053 ppm (100 μg/m3) 0.053 ppm (100 μg/m3) Pb 24-hour average 1 quarter arithmetic mean 1.5 μg/m3 1.5 μg/m3 1.5 μg/m3 1. In 1987, National standards for PM-10 replaced those for TSP. 2. Arithmetic mean over the 3 most current years. 3. In July 1997, a percentile-based statistic replaced the 2nd maximum, but in May 1999 the 2nd maximum standard was reinstated. 4. Determined by adjusting for incomplete days and averaging over the most recent 3 consecutive, complete calendar years. 5. Arithmetic mean value over the most recent 3 consecutive, complete calendar years. 6. On April 1, 2000, North Carolina adopted the EPA PM2.5 and Ozone standards. On May 14, 2000, the US Court of Appeals ruled the new EPA PM2.5 standard vacated and the new 8-hour ozone standard as unenforceable. On appeal to the US Supreme Court the new standard was upheld. 7. To attain this standard, the 3-year average of the 98th percentile of 24-hour concentrations at each population-oriented monitor within an area must not exceed 35 μg/m3 (effective December 17, 2006). 8. On May 27, 2000, the one-hour ozone standard was rescinded by the Environmental Management Commission based on EPA guidance. The one-hour standard is being reinstated by EPA. 9 4 Ambient Air Quality Monitoring Program The North Carolina Division of Air Quality, three local air pollution control programs, and one tribal program (Appendix A) performed ambient monitoring and analyses of samples in 2006. Ambient air monitoring data are used to determine whether air quality standards are being met; to assist in enforcement actions; to determine the improvement or decline of air quality; to determine the extent of allowable industrial expansion; and to provide air pollution information to the public. A list of all monitoring sites active in 2006 is presented in Table 4.1 and shown as a map in Figure 4.1. The locations of sites for individual pollutants are shown in Figures 5.1, 5.4, 5.8, 5.11, 5.14, and 5.17. In general, ambient monitors are operated year-round, but in some cases seasonal variations in pollutant levels make it feasible to suspend sampling at certain times. Ambient carbon monoxide associated with transportation and heating tends to produce significant concentrations only in cold weather conditions, so (with the US EPA's permission) we generally operate these monitors only from October through March. Ozone concentrations, by contrast, are correlated positively with ambient temperature. US EPA regulations accordingly require monitoring in NC from April through October. Along with ozone at some locations, we also monitor ozone precursor pollutants. Indeed, one of the ozone precursors is carbon monoxide. See 5.4 for more information about seasonal carbon monoxide monitoring and 5.5 for more information about seasonal ozone monitoring. Siting of monitors involves several considerations, including size of the area represented, distance from roadways and nearby sources, unrestricted air flow, safety, availability of electricity and security. Each site has a defined monitoring objective, and annual evaluations are conducted to ensure that the objectives are met. The four basic monitoring objectives are to determine: the highest concentration expected in an area; representative concentrations in areas of high population density; the impact of significant sources or source categories on ambient air quality; general background concentration levels. All monitors have known precision, accuracy, interferences and operational parameters. The monitors as well as all measurement devices are carefully calibrated at predetermined frequencies, varying from daily to quarterly. Measurements are traceable to National Institute of Standards and Technology (NIST), when standards are available. Monitoring and analyses are performed according to a set of standard operating procedures. Field personnel visit manual 10 sampling sites once every six days to replace sample media and check the operation and calibration of monitors. Personnel check continuous monitors at least twice monthly for correct instrument operation. Monitoring agencies carry out quality assurance activities to determine the quality of the collected ambient data, improve the quality of the data and evaluate how well the monitoring system operates. The goal of quality assurance activities is to produce high quality air pollution data with defined completeness, precision, accuracy, representativeness and comparability. Microprocessors are used at most sites to collect the data. A computerized telemetry system aids in assembly of the data for submission to the US EPA. This enhances data validity, minimizes travel costs, and allows real-time data to be available by computer polling when needed. Numerous checks are performed to ensure that only valid data are reported. Figure 4.1 Monitoring Sites Active in 200611 Table 4.1 Ambient Air Monitoring Sites Operated in North Carolina, 2006 SITE ADDRESS POLLUTANTS COUNTY 37-001-0002 827 S GRAHAM & HOPEDALE RD PM2.5 ALAMANCE BURLINGTON 37-003-0004 106 WAGGIN TRAIL RD O3 ALEXANDER TAYLORSVILLE 37-011-0002 7510 BLUE RIDGE PARKWAY SPUR O3 AVERY LINVILLE 37-013-0006 NC 306 @ PCS ENTRANCE SO2 BEAUFORT AURORA 37-021-0030 ROUT 191 SOUTH BREVARD RD O3 BUNCOMBE ASHEVILLE 37-021-0034 175 BINGHAM ROAD PM2.5 BUNCOMBE ASHEVILLE 37-027-0003 HWY 321 NORTH O3 CALDWELL LENOIR 37-033-0001 7074 CHERRY GROVE RD O3 PM2.5 CO CASWELL REIDSVILLE 37-035-0004 1650 1ST STREET PM10 PM2.5 CATAWBA HICKORY 37-035-0006 320 3RD STREET DR SW PM2.5 CATAWBA HICKORY 37-037-0004 325 RUSSETT RUN ROAD O3 PM2.5 CHATHAM PITTSBORO 37-051-0007 CUMBERLAND CO ABC BOARD, 1705 OWEN DR CO CUMBERLAND FAYETTEVILLE 37-051-0008 1/4 MILE SR1857/US301/1857 O3 CUMBERLAND WADE 37-051-0009 4533 RAEFORD RD PM10 PM2.5 CUMBERLAND FAYETTEVILLE 37-051-1003 3625 GOLFVIEW RD O3 SO2 CUMBERLAND HOPE MILLS 12 SITE ADDRESS POLLUTANTS COUNTY 37-057-0002 SOUTH SALISBURY STREET PM2.5 DAVIDSON LEXINGTON 37-059-0002 246 MAIN STREET O3 DAVIE COOLEEMEE 37-061-0002 HIGHWAY 50 PM2.5 DUPLIN KENANSVILLE 37-063-0001 HEALTH DEPT 300 E MAIN STREET PM10 PM2.5 DURHAM DURHAM 37-063-0013 2700 NORTH DUKE STREET CO O3 DURHAM DURHAM 37-065-0004 900 SPRINGFIELD RD PM2.5 EDGECOME ROCKY MOUNT 37-065-0099 7589 NC HIGHWAY 33 NW O3 PM10 EDGECOME TARBORO 37-067-0022 1300 BLK HATTIE AVENUE PM10 O3 SO2 NO2 PM2.5 FORSYTH WINSTON-SALEM 37-067-0023 1401 CORPORATION PARKWAY CO PM10 FORSYTH WINSTON-SALEM 37-067-0028 6496 BAUX MOUNTAIN ROAD O3 FORSYTH WINSTON-SALEM 37-067-0030 FRATERNITY CHURCH O3 PM2.5 FORSYTH WINSTON-SALEM 37-067-1008 3656 PIEDMONT MEMORIAL DRIVE O3 FORSYTH WINSTON-SALEM 37-069-0001 431 S. HILLSBOROUGH STREET O3 FRANKLIN FRANKLINTON 37-071-0016 1622 EAST GARRISON BLVD PM2.5 GASTON GASOTNIA 37-075-0001 FOREST ROAD 423 SPUR O3 GRAHAM KILMER 13 SITE ADDRESS POLLUTANTS COUNTY 37-077-0001 WATER TREATMENT PLANT JOHN UMSTEAD HOSP O3 GRANVILLE BUTNER 37-081-0013 205 WILOUGHBY BLVD PM2.5 PM10 O3 GUILFORD GREENSBORO 37-081-1011 401 WEST WENDOVER CO GUILFORD GREENSBORO 37-087-0004 2177 ASHEVILLE ROAD O3 HAYWOOD WAYNESVILLE 37-087-0010 9 MAIN STREET PM2.5 HAYWOOD WAYNESVILLE 37-087-0035 TOWER BLUE RIDGE PARKWAY O3 HAYWOOD MILE MARKER 410 37-087-0036 GREAT SMOKY MOUNTAINS O3 HAYWOOD NATIONAL PARK 37-089-1006 CORNER OF ALLEN & WASHINGTON ST'S PM10 HENDERSON HENDERSONVILLE 37-099-0005 BARNET KNOB FIRE TOWER RD O3 JACKSON CHEROKEE 37-099-0006 US ROUTE 19 NORTH PM2.5 JACKSON CHEROKEE RESERVATION 37-101-0002 1338 JACK ROAD O3 JOHNSTON CLAYTON 37-107-0004 HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH O3 PM2.5 LENOIR KINSTON 37-109-0004 1487 RIVERVIEW ROAD O3 LINCOLN LINCOLNTON 37-111-0004 BALWIN AVENUE (EAST MARION JR. HIGH SCHOOL) PM2.5 MC DOWELL MARION 37-117-0001 1210 HAYES STREET O3 PM2.5 SO2 MARTIN JAMESVILLE 14 SITE ADDRESS POLLUTANTS COUNTY 37-119-0003 FIRE STATION # 11, 620 WEST 28TH STREET PM10 MECKLENBURG CHARLOTTE 37-119-0041 1130 EASTWAY DRIVE CO SO2 PM2.5 O3 NO2 MECKLENBURG CHARLOTTE 37-119-0042 1935 EMERYWOOD DRIVE PM2.5 MECKLENBURG CHARLOTTE 37-119-043 513 RADIO ROAD PM2.5 MECKLENBURG 37-119-1001 FILTER PLANT PM10 MECKLENBURG DAVIDSON 37-119-1005 400 WESTINGHOUSE BLVD. O3 PM10 MECKLENBURG CHARLOTTE 37-119-1009 29 N @ MECKLENBURG CAB CO. O3 MECKLENBURG CHARLOTTE 37-121-0001 CITY HALL, SUMMIT STREET PM2.5 MITCHELL SPRUCE PINE 37-123-0001 112 PERRY DRIVE PM2.5 MONTGOMERY CANDOR 37-129-0002 6028 HOLLY SHELTER ROAD O3 PM2.5 NEW HANOVER CASTLE HAYNE 37-129-0006 HIGHWAY 421 NORTH SO2 NEW HANOVER WILMINGTON 37-133-0005 617 HENDERSON DR PM2.5 PM10 ONSLOW JACKSONVILLE 37-135-0007 MASON FARM ROAD PM2.5 ORANGE CHAPEL HILL 37-145-0003 STATE ROAD 1102 & NC 49 O3 PERSON ROXBORO 37-147-0005 851 HOWELL STREET PM2.5 PITT GREENVILLE 37-147-0099 US 264 NEAR WATER TOWER O3 PITT FARMVILLE 15 SITE ADDRESS POLLUTANTS COUNTY 37-155-0005 1170 LINKHAW ROAD PM2.5 ROBESON LUMBERTON 37-157-0099 6371 NC 65 @ BETHANY SCHOOL O3 ROCKINGHAM BETHANY 37-159-0021 301 WEST ST & GOLD HILL AVENUE CO O3 PM2.5 ROWAN ROCKWELL 37-159-0022 925 NORTH ENOCHVILLE AVENUE O3 ROWAN CHINA GROVE 37-173-0002 CENTER ST/PARKS & RECREATION FACILITY O3 PM2.5 PM10 SWAIN BRYSON CITY 37-179-0003 701 CHARLES STREET O3 UNION MONROE 37-183-0014 3801 SPRING FOREST ROAD O3 PM2.5 PM10 SO2 CO WAKE RALEIGH 37-183-0016 201 NORTH BROAD STREET O3 WAKE FUQUAY-VARINA 37-183-0018 US HIGHWAY 70 WEST AND NC HIGHWAY 50 NORD CO WAKE RALEIGH 37-189-0003 361 JEFFERSON ROAD PM2.5 WATAUGA BOONE 37-191-0005 DILLARD MIDDLE SHOOL, DEVEREAU STREET PM2.5 PM10 WAYNE GOLDSBORO 37-199-0003 STATE HIGHWAY 128 O3 YANCEY BURNSVILLE 37-199-0004 NEW LOC MT MITCHELL O3 YANCEY Sites operated in 74 2006 16 5 Pollutant Monitoring Results Air quality in a given area is affected by many factors, including meteorological conditions, the location of pollutant sources, and the amount of pollutants emitted from them. The speed and direction of air movement determine whether pollutant emissions cause exceedances of the ambient air quality standards and where those exceedances will occur. Atmospheric stability, precipitation, solar radiation and temperature also affect pollutant concentrations. Geographic factors that affect concentrations include variables such as whether an area is urban or rural, and whether the area has mountains, valleys or plains. Important economic factors affecting air quality include concentration of industries, conditions of the economy, and the day of the week. Air quality also may be influenced by “exceptional events” in the short term. Exceptional events may be either natural (e.g., forest fire) or manmade (e.g., construction or demolition). Unusual data that can be attributed to an exceptional event are considered biased and may be omitted from data summaries when they are not representative of normal conditions. In the tabular listings in this report, data affected by exceptional events are excluded, and are omitted from summaries in charts. However they are addressed in the text of the report. A list of typical exceptional events is given in Appendix B. Data for the 2006 ambient air quality report were collected at 122 air pollutant monitors operated by state and local agencies in North Carolina (listed in Appendix A). To minimize operating expenses, some sulfur dioxide monitors are operated only every third year. Four of the 122 monitors used for this report operated most recently in 2004 or 2005. 5.1 Total Suspended Particulates Total Suspended Particulate matter (TSP) is collected on filters using a “high volume” sampler (an EPA Reference Method). The sampler motor is set and calibrated to an air flow rate of 40±4 cubic feet per minute. Gravimetric analysis is performed by comparing the exposed filter weight to the unexposed filter weight. Weights are measured to the nearest 0.1 milligram. The difference between the exposed and unexposed weights is the amount of particulate collected from a known volume of air. The state and local program agencies discontinued routine ambient TSP sampling at the end of 2000, but resumed a limited sampling program again in 2003. In 2006 seven sites were used to monitor TSP and 361 samples were collected. A detailed summary of 17 the data from each site is given in Table 5.1. No sample exceeded the N.C. TSP ambient air quality standards in 2006. The highest 24-hour average was 69 g/m3 , which was 46 percent of the standard. This value occurred at the 6028 Holly Shelter Road site in Castle Hayne. Attainment status is based on the second highest 24-hour concentration and on the geometric mean of all the 24-hour concentrations at a given site. The largest geometric mean TSP average was 29 g/m3, which is 39 percent of the level of the air quality standard. This value occurred at the 1650 1st Street site in Hickory and 205 Willoughby Boulevard site in Greensboro. Table 5.1 Total Suspended Particulates in Micrograms Per Cubic Meter for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAX ARITH MEAN GEOM MEAN GEOM SD COUNTY 1st 2nd 3rd 4th 37-035-0004 1650 1st STREET 53 68 60 55 53 33 29 1.7 CATAWBA HICKORY 37-081-0013 205 WILLOUGHBY BLVD 42 65 55 52 52 32 29 1.6 GUILFORD GREENSBORO 37-087-0011 HAYWOOD PROSPECT AND NORTHSIDE STR 58 62 50 50 49 29 26 1.7 CANTON 37-117-0001 1210 HAYES STREET 60 46 43 37 35 22 20 1.4 MARTIN JAMESVILLE 37-129-0002 6028 HOLLY SHELTER RD 56 69 40 36 35 21 19 1.6 NEW HANOVER CASTLE HAYNE 37-155-0005 1170 LINKHAW ROAD 56 57 49 48 43 28 25 1.7 ROBESON LUMBERTON 37-183-0014 3801 SPRING FOREST RD 36 65 58 52 51 34 32 1.5 WAKE RALEIGH Total Samples 361 Total Sites Sampled 7 18 5.2 PM10 State and local program agencies in North Carolina use high volume samplers and size selective inlets to collect PM10 samples. A gravimetric analysis procedure (EPA Reference Method) is used to analyze the samples. In 2006, 1,717 ordinary 24-hour samples of PM10 were collected from monitors located at 15 sites. A map of the PM10 sampling sites is shown in Figure 5.1, and a detailed summary of the data from each site is given in Table 5.2. There were no exceedances of the PM10 ambient air quality standards in 2006. The highest 24-hour maximum concentration was 69 g/m3, or about 46 percent of the standard (150 g/m3). The highest annual arithmetic mean was 31.1 g/m3, which is about 62 percent of the standard (50 g/m3). The second highest 24-hour concentrations are shown by county in Figure 5.2 and the annual arithmetic means are shown in Figure 5.3. (In counties with more than one PM10 monitoring site, the concentration reported in Figure 5.2 is the county-wide second maximum 24-hour concentration, and the mean reported in Figure 5.3 is the maximum arithmetic mean for the county.) Figure 5.1 Location of PM10 Monitoring Sites 19 Table 5.2 PM10 in Micrograms Per Cubic Meter for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-035-0004 1650 1ST. ST. 59 56 45 44 42 21.6 CATAWBA HICKORY 37-051-0009 CUMBERLAND 4533 RAEFORD ROAD 60 41 40 35 35 18.8 FAYETTEVILLE 37-063-0001 DURHAM HEALTH DEPT 300 E MAIN ST 60 38 31 31 30 18.1 DURHAM 37-065-0099 7589 NC HWY 33 NW 59 45 38 36 34 15.9 EDGECOMBE LEGGETT 37-067-0022 1300 BLK. HATTIE AVE 365 51 45 41 41 19.4 FORSYTH WINSTON-SALEM 37-067-0023 FORSYTH 1401 CORPORATION PARKWAY 362 53 51 47 47 23.0 WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 46 43 33 32 21.2 GUILFORD GREENSBORO 37-089-1006 HENDERSON CORNER OF ALLEN & WASHINGTON STS 59 52 42 35 35 20.4 HENDERSONVILLE 37-119-0003 MECKLENBURG FIRE STA #11 620 MORETZ STREET 60 47 46 44 44 25.5 CHARLOTTE 37-119-1001 FILTER PLANT 58 53 42 41 40 22.2 MECKLENBURG DAVIDSON 37-119-1005 400 WESTINGHOUSE BLVD. 60 69 62 56 54 31.1 MECKLENBURG CHARLOTTE 37-133-0005 617 HENDERSON DRIVE 60 44 38 31 29 16.1 ONSLOW JACKSONVILLE 37-173-0002 CENTER ST/PARKS 7 REC 59 53 40 31 31 17.9 SWAIN FACILITY 37-183-0014 3801 SPRING FOREST RD. 300 43 43 41 39 19.5 WAKE RALEIGH 37-191-0005 WAYNE DILLARD MIDDLE SCHOOL DEVEREAU ST 53 41 34 31 30 18.2 GOLDSBORO Total Samples 1,717 Total Sites Sampled 15 20 Figure 5.2 PM10: Second Highest 24-Hour Averages, 2006 Figure 5.3 PM10: Maximum Annual Arithmetic Means, 2006 21 5.3 Fine Particulate Matter, (PM2.5) In 2006, 35 sites were used to monitor PM2.5 and 5,176 samples were collected. A map of the PM2.5 sampling sites is shown in Figure 5.4 and a detailed summary of the data from each site is given in Table 5.3. There was one exceedance of the PM2.5 24-hour ambient air quality standards in 2006, at the Perry Drive site in Montgomery County. This highest 24-hour concentration was 69.2 g/m3, or about 6 percent of the 2005 standard (65 g/m3), but according to a new implemented standard in 2006 (35 g/m3) there were 17 exceedances of the PM2.5 24-hr ambient air quality standard (See Table 5.3). The highest annual arithmetic mean was 15.16 g/m3, which is about 1 percent over the level of the standard (15 g/m3), at Hickory in Catawba County. The other monitor that exceeded the annual arithmetic mean standard in 2006 was South Salisbury Street in Davidson County. (See Table 5.3). NAAQS attainment is based on both the level of the 98th percentile concentration of 24 hour averages and weighted annual means (Table 3.1). The 98th percentile concentrations are shown by county in Figure 5.5, and the annual arithmetic means are shown in Figure 5.6. (In counties with more than one monitoring site, the concentration reported in Figure 5.5 is the maximum 98th percentile and the mean reported in Figure 5.6 is the maximum arithmetic mean for the county.) Figure 5.7 is a map of “design values” for PM2.5, computed from the highest 3-year average arithmetic mean in each county for 2004 through 2006, using the federal reference method monitors. Thirty-one counties have enough reported data to compute this metric correctly, and two of them appear to be violating the ambient standard that is due to be implemented. Attainment decisions for PM2.5 will be based on the design values observed during 2004 through 2006, which may or may not resemble the values illustrated here. 22 Figure 5.4 Location of PM2.5 Monitoring Sites Table 5.3 PM2.5 in Micrograms Per Cubic Meter for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA PERCENTILE ARITH MEAN COUNTY 1st 2nd 3rd 4th 98TH 37-001-0002 ALAMANCE 827 S. GRAHAM & HOPEDALE RD 120 35.2 35.2 28.7 28.3 28.7 13.52 BURLINGTON 37-021-0034 BUNCOMBE 175 BINGHAM ROAD 120 35.5 31.5 30.9 30.3 30.9 12.51 ASHEVILLE 37-033-0001 CASWELL 7074 CHERRY GROVE RECREATION 119 32.3 30.9 29.9 29.7 29.9 13.29 37-035-0004 1650 1ST. ST. 122 38.1 34.4 32.9 32.7 32.9 15.16 CATAWBA HICKORY 37-035-0006 320 3RD ST DR SW 58 31.6 27.0 26.9 25.8 27.0 13.50 CATAWBA HICKORY 37-037-0004 325 RUSSETT 117 34.4 32.3 28.4 28.2 28.4 12.29 CHATHAM PITTSBORO 37-051-0009 CUMBERLAND 4533 RAEFORD ROAD 121 33.2 30.1 30.0 28.9 30.0 13.60 FAYETTEVILLE 37-057-0002 DAVIDSON SOUTH SALISBURY STREET 120 40.2 31.3 31.0 31.0 31.0 15.13 LEXINGTON 23 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA PERCENTILE ARITH MEAN COUNTY 1st 2nd 3rd 4th 98TH 37-061-0002 HWY 50 116 30.0 29.4 27.5 25.3 27.5 11.06 DUPLIN KENANANSVILLE 37-063-0001 DURHAM HEALTH DEPT 300 E MAIN ST 339 36.5 35.2 34.4 32.3 30.0 13.65 DURHAM 38-065-0004 900 SPRINGFIELD 117 41.8 32.5 27.0 26.9 27.0 12.79 EDGECOMBE ROCKY MOUNT 37-067-0022 FORSYTH 1300 BLOCK, HATTIE AVENUE 302 43.3 33.2 32.8 32.3 30.8 14.18 WINSTON-SALEM 37-067-0030 FORSYTH FRATERNITY CHURCH ROAD 113 32.6 32.3 31.8 30.7 31.8 14.11 WINSTON-SALEM 37-071-0016 GASTON 1622 EAST GARRISON BLVD 119 36.3 32.2 29.5 28.9 29.5 14.30 GASTONIA 37-081-0013 GUILFORD 205 WILOUGHBY BLVD 235 39.4 34.2 32.9 31.8 31.3 14.44 GREENSBORO 37-087-0010 9 MAIN STREET 119 33.4 30.6 30.2 28.8 30.2 12.76 HAYWOOD WAYNESVILLE 37-099-0006 US RT 19 NORTH 107 27.6 25.2 24.4 24.1 24.4 11.84 JACKSON CHEROKEE RES 37-107-0004 LENOIR CORNER HWY 70 EAST 116 31.0 25.7 23.3 22.2 23.3 10.51 KINSTON 37-111-0004 BALDWIN AVE 119 36.9 33.8 32.2 30.8 32.2 13.76 MC DOWELL MARION 37-117-0001 1210 HAYES ST 114 35.6 26.3 24.2 23.4 24.2 10.66 MARTIN JAMESVILLE 37-119-1041 MECKLENBURG 1130 EASTWAY DRIVE 350 35.8 35.5 33.9 33.0 30.7 14.59 CHARLOTTE 37-119-1042 MECKLENBURG 1935 EMERYWOOD DRIVE 119 35.7 33.5 31.5 30.7 31.5 14.63 CHARLOTTE 37-119-0043 MECKLENBURG 513 RADIO ROAD 336 35.7 34.0 33.8 31.9 29.9 13.95 37-121-0001 MITCHELL CITY HALL SUMMIT ST 120 33.5 31.0 30.9 30.3 30.9 12.25 SPRUCE PINE 37-123-0001 112 PERRY DRIVE 120 69.2 29.7 29.2 28.8 29.2 12.37 MONTGOMERY CANDOR 24 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA PERCENTILE ARITH MEAN COUNTY 1st 2nd 3rd 4th 98TH 37-129-0002 NEW HANOVER 6028 HOLLY SHELTER RD 118 27.1 27.0 25.8 22.7 25.8 9.75 37-133-0005 ONSLOW 617 HENDERSON DRIVE 118 28.3 25.5 24.6 23.4 24.6 10.56 JACKSONVILLE 37-135-0007 ORANGE MASON FARM ROAD 122 33.6 32.3 31.3 28.6 31.3 12.95 CHAPEL HILL 37-147-0005 PITT 851 HOWELL STREET 116 36.1 28.6 25.3 24.1 25.3 11.14 GREENVILLE 37-155-0005 ROBESON 1170 LINKHAM ROAD 121 33.2 30.3 28.4 27.8 28.4 12.49 LUMBERTON 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 119 36.9 33.5 29.1 29.1 29.1 14.22 ROCKWEL 37-173-0002 SWAIN CENTER ST/PARKS 7 REC 118 29.0 27.0 26.7 26.6 26.7 11.87 FACILITY 37-183-0014 WAKE 3801 SPRING FOREST RD 250 27.7 26.4 25.5 24.5 24.4 12.27 RALEIGH 37-189-0003 WATAUGA 361JEFFERSON HWY 119 30.5 29.8 29.2 28.5 29.2 11.24 BOONE 37-191-0005 WAYNE DILLARD MIDDLE SCHOOL 117 35.1 32.6 32.5 27.3 32.5 12.90 GOLDSBORO Total Samples 5,176 Total Sites Sampled 35 25 Figure 5.5 PM2.5: 98th Percentile, 2006 Figure 5.6 PM2.5: Annual Arithmetic Means, 2006 26 Figure 5.7 PM2.5 Design Values by County, 2004-2006 27 5.4 Carbon Monoxide Carbon monoxide (CO) data were collected for two purposes in 2006: to determine attainment status of the ambient air quality standard, and to gather data on CO as an ozone precursor. The carbon monoxide associated with ozone formation consists of very low concentrations (not greater than 2 ppm) collected at special sites considered optimal for input to a large photochemical grid model. This report will not further discuss the role of CO as an ozone precursor, but these data and more information are available on request from the Division of Air Quality (see the Preface for a mailing address). To assess CO attainment status, the Division of Air Quality collected data from monitors in Durham, Greensboro and Raleigh, and local program agencies collected data from three monitors in Winston-Salem and Charlotte using EPA Reference or equivalent methods to measure the concentrations. In 2006, five sites were used to monitor CO and 28,259 valid hourly averages were collected. The data were collected from monitors: - Charlotte, Winston-Salem-all year; - Greensboro, Raleigh and Fayetteville – colder months. A map of the CO sampling sites is shown in Figure 5.8, and a detailed summary of the data from each site is presented in Table 5.4. There were no exceedances of the CO ambient air quality standards in 2006. The highest 1-hour average was 4.0 parts per million (ppm), or about 11 percent of the standard (35 ppm). This value occurred at the ABC Board site in Fayetteville. The highest 8-hour average was 3.0 ppm, at the ABC Board site in Fayetteville, which is about 33 percent of the standard. The second highest 1-hour concentrations in each county are shown in Figure 5.9 and the second highest 8-hour concentrations are shown in Figure 5.10. Historical data have demonstrated that high concentrations of CO occur more frequently in autumn and winter than during the warmer months of the year. There are three main reasons for this seasonal variation: (1) North Carolina experiences more atmospheric inversions in colder months, trapping air pollutants at low heights; (2) motor vehicles emit more CO due to inefficient combustion during cold starts and warm up; and (3) during colder temperatures, more fuel is burned for comfort heating. All areas monitored are attaining the ambient air quality standards for carbon monoxide. Several factors have reduced CO concentrations, with the most significant being that older vehicles are gradually being replaced with newer, more efficient vehicles. The motor vehicle Inspection and Maintenance program (in effect in 48 counties [NC Dept of Environmental and Natural Resources, N.D]) is an intentional control strategy that helps assure cleaner-running cars. Other factors include increased news media interest and public awareness, and the reporting of the Air Quality Index (see Chapter 6 of this report). As a result of greater public awareness, more cars are kept in better running condition, thus operating more cleanly. Traffic flow improvements such as new roads and better coordinated traffic signals also help reduce CO. 28 Figure 5.8 Location of Carbon Monoxide Monitoring Sites Table 5.4 Carbon Monoxide in Parts Per Million for 2006 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA EIGHT-HOUR MAXIMA COUNTY 1st 2nd 1st 2nd 37-051-0007 ABC BOARD, 1705 OWEN DRIVE 3,641 4.0 3.8 3.0 2.7 CUMBERLAND FAYETTEVILLE 37-067-0023 1401 CORPORATION PKY 8,700 3.2 3.2 2.7 2.4 FORSYTH WINSTON-SALEM 37-081-1011 401 WEST WENDOVER 3,552 2.9 2.8 2.6 2.5 GUILFORD GREENSBORO 37-119-0041 1130 EASTWAY DRIVE 8,656 3.6 3.0 2.3 2.3 MECKLENBURG CHARLOTTE 37-183-0018 WAKE US HWY 70 WEST AND NC HWY 50 NORTH 3,710 3.3 3.3 2.6 2.5 RALEIGH Total Samples 28,259 Total Sites Sampled 5 29 Figure 5.9 Carbon Monoxide: Second Highest 1-Hour Concentration, 2006 Figure 5.10 Carbon Monoxide: Second Highest Non-overlapping 8-Hour Concentration, 2006 30 5.5 Ozone Ozone (O3) concentrations are measured using EPA reference or equivalent continuous monitors. Ozone is a seasonal pollutant formed in the atmosphere as a result of many chemical reactions that occur in sunlight, mainly during the warmer months. Thus, most ozone monitors only operate from April through October. The state and local program agencies operated 42 monitoring sites in 2006 during the ozone season, April through October. A map of the O3 sampling sites is presented in Figure 5.11, and a detailed summary of the one-hour data from each site is given in Table 5.5, and the 8-hour data in Table 5.6. These 42 monitoring sites provided 8,392 site-days of valid data (a success rate of 93 percent for the days that sampling is required). There were no exceedances of the 1-hour ozone standard in North Carolina in 2006. The one-hour standard is exceeded when one valid one-hour average exceeds 0.124 ppm at a site and the expected number of exceedances is greater than 1. (To exceed the standard, the largest average must be larger than 0.12 ppm when rounded to two significant digits. The “expected number” of exceedances is determined from a 3-year average of exceedance day counts for an area. Moreover, when any ozone sampling day does not have a valid maximum ozone measurement for any reason, the missing day can be counted as an estimated exceedance day under certain circumstances [40 CFR 50 App. J, US EPA 1993, p. 767-768]. Table 5.5 gives both the actually measured and the estimated number of exceedance days at each site.) The 8-hour standard was exceeded a total of 48 times at the 42 sites that monitored for O3. Eighteen monitors had at least one exceedance. The largest number at one monitor was eight in Charlotte (Mecklenburg County). These exceedances were distributed over 20 days during the ozone season when at least one site within the state recorded values greater than 0.085 ppm. The second highest 1-hour concentrations in each county are shown in Figure 5.12 for areas with one or more monitors active in 2006. Monitors whose second highest 1-hour concentration exceeds 0.124 ppm potentially violate the EPA one-hour standard (although it is no longer in effect in North Carolina). Historical average fourth-highest 8-hour concentrations of O3 in counties where monitors were operated in 2006 are shown in Figure 5.13. Monitors whose fourth-highest 8-hour ozone concentration (averaged over three years) exceeds 0.084 ppm are deemed in violation of the EPA 8-hour standard.31 Figure 5.11 Location of Ozone Monitoring Sites Table 5.5 One-Hour Ozone in Parts Per Million for 2006 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST 37-003-0004 106 WAGGIN’ TRAIL 5136 .094 .091 .089 .088 0 0.00 ALEXANDER TAYLORSVILLE 37-011-0002 7510 BLUE RIDGE 4896 .079 .076 .071 .070 0 0.00 AVERY 37-021-0030 ROUTE 191 SOUTH BREVARD RD 5136 .092 .090 .083 .082 0 0.00 BUNCOMBE ASHEVILLE 37-027-0003 HWY 321 NORTH 5088 .095 .088 .087 .084 0 0.00 CALDWELL LENOIR 37-033-0001 7074 CHERRY GROVE 4968 .092 .089 .086 .086 0 0.00 32 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST CASWELL REIDSVILLE 37-037-0004 325 RUSSETT RUN ROAD 5112 .094 .084 .082 .080 0 0.00 CHATHAM PITTSBORO 37-051-0008 1/4MI SR1857/US301/1857 5040 .090 .083 .083 .082 0 0.00 CUMBERLAND WADE 37-051-1003 3625 GOLFVIEW ROAD 5088 .093 .091 .085 .085 0 0.00 CUMBERLAND HOPE MILLS 37-059-0002 246 MAIN STREET 5136 .103 .096 .093 .093 0 0.00 DAVIE COOLEEMEE 37-063-0013 2700 NORTH DUKE STREET 5088 .103 .097 .091 .085 0 0.00 DURHAM DURHAM 37-065-0099 7589 NC HWY 33-NW 5136 .093 .087 .084 .081 0 0.00 EDGECOMBE LEGGETT 37-067-0022 1300 BLK. HATTIE AVENUE 5136 .098 .097 .097 .096 0 0.00 FORSYTH WINSTON-SALEM 37-067-0028 6496 BAUX MOUNTAIN ROAD 5136 .087 .085 .078 .075 0 0.00 FORSYTH WINSTON-SALEM 37-067-0030 FRATERNITY CHURCH ROAD 5136 .105 .094 .089 .087 0 0.00 FORSYTH WINSTON-SALEM 37-067-1008 3656 PIEDMONT MEMORIAL DRIVE 5136 .105 .100 .098 .092 0 0.00 FORSYTH WINSTON-SALEM 37-069-0001 431 S. HILLBOROUGH ST 5136 .105 .091 .090 .088 0 0.00 FRANKLIN FRANKLINTON 37-075-0001 FOREST ROAD 423 SPUR 5088 .109 .090 .087 .086 0 0.00 GRAHAM KILMER 37-077-0001 WATER TREATMENT PLANT, JOHN UMSTEAD HOSPITAL 5112 .108 .095 .093 .093 0 0.00 GRANVILLE BUTNER 37-081-0013 205 WILOUGHBY BLVD 4104 .113 .101 .093 .092 0 0.00 GUILFORD GREENSBORO 33 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST 37-087-0004 2177 SCHEVILLS ROAD 5136 .083 .082 .076 .075 0 0.00 HAYWOOD WAYNESVILLE 37-087-0035 TOWER BLUE RIDGE PARKWAY 4944 .104 .092 .090 .087 0 0.00 HAYWOOD MILE MARKER 410 37-087-0036 GREAT SMOKY MOUNTAIN 4920 .092 .088 .081 .079 0 0.00 HAYWOOD NATIONAL PARK 37-099-0005 BARNET KNOB FIRE TOWER 4896 .091 .088 .085 .085 0 0.00 JACKSON CHEROKEE 37-101-0002 1338 JACK ROAD 5112 .089 .088 .084 .083 0 0.00 JOHNSTON CLAYTON 37-107-0004 CORNER HWY EAST 4920 .095 .087 .085 .083 0 0.00 LENOIR KINSTON 37-109-0004 1487 RIVERVIEW ROAD 5088 .119 .113 .101 .095 0 0.00 LINCOLN LINCOLNTON 37-117-0001 1210 HAYES STREET 5088 .086 .082 .081 .080 0 0.00 MARTIN JAMESVILLE 37-119-0041 1130 EASTWAY DRIVE 5112 .122 .112 .110 .107 0 0.00 MECKLENBURG CHARLOTTE 37-119-1005 400 WESTINGHOUSE BLVD. 5136 .105 .097 .097 .097 0 0.00 MECKLENBURG CHARLOTTE 37-119-1009 29 N@ MECKLENBURG CAB CO 5112 .120 .115 .107 .106 0 0.00 MECKLENBURG CHARLOTTE 37-129-0002 6028 HOLLY SHELTER RD 5016 .088 .085 .085 .081 0 0.00 NEW HANOVER CASTLE HAYNE 37-145-0003 STATE ROAD 1102 & NC49 5136 .096 .090 .089 .086 0 0.00 PERSON ROXBORO 37-147-0099 US 264 NEAR WATTER TOWER 5136 .102 .083 .083 .081 0 0.00 PITT FARMVILLE 34 SITE NUMBER ADDRESS NUM OBS DAILY 1-HR MAXIMA NO. VALUES > 0.125 COUNTY 1st 2nd 3rd 4th MEAS EST 37-157-0099 6371 NC 65 @ BETHANY SCHOOL 5136 .097 .091 .089 .088 0 0.00 ROCKINGHAM BETHANY 37-159-0021 301 WEST ST & GOLD HILL AVENUE 5136 .119 .104 .101 .098 0 0.00 ROWAN ROCKWELL 37-159-0022 925 N ENOCHVILLE AVE 5136 .111 .110 .109 .107 0 0.00 ROWAN CHINA GROVE 37-173-0002 CENTER STREET 5112 .072 .070 .070 .069 0 0.00 SWAIN BRYSON CITY 37-179-0003 701 CHARLES STREET 3984 .115 .111 .097 .092 0 0.00 UNION MONROE 37-183-0014 3801 SPRING FOREST ROAD 4872 .101 .093 .091 .090 0 0.00 WAKE RALEIGH 37-183-0016 201 NORTH BROAD STREET 5064 .098 .088 .084 .083 0 0.00 WAKE FUQUAY-VARINA 37-199-0003 STATE HIGHWAY 128 1248 .094 .084 .076 .071 0 0.00 YANCY 37-199-004 YANCY BURNSVILLE NEW LOC MT 3432 .091 .084 .084 .080 0 0.00 Total Samples 205,680 0 0.00 Total Sites Sampled 42 35 Table 5.6 Eight-Hour Ozone in Parts Per Million for 2006 SITE NUMBER ADDRESS VALID DAYS VALID DAILY 8-HR MAXIMUM N0. VALUES COUNTY .>.085 1st 2nd 3rd 4th MEAS 37-003-0004 106 WAGGIN’ TRAIL 201 .082 .082 .077 .076 0 ALEXANDER TAYLORSVILLE 37-011-0002 7510 BLUE RIDGE 200 .072 .070 .068 .067 0 AVERY 37-021-0030 ROUT 191 SOUTH BREVARD RD 214 .083 .078 .071 .071 0 BUNCOMBE ASHEVILLE 37-027-0003 HWY 321 NORTH 207 .081 .077 .076 .076 0 CALDWELL LENOIR 37-033-0001 7074 CHERRY GROVE RD 205 .077 .077 .075 .075 0 CASWELL REIDSVILLE 37-037-0004 325 RUSSETT RUN 211 .078 .074 .071 .070 0 CHATHAM PITTSBORO 37-051-0008 1/4MI SR1857/US301/1857 198 .080 .073 .072 .072 0 CUMBERLAND WADE 37-051-1003 3625 GOLFVIEW ROAD 210 .077 .075 .074 .074 0 CUMBERLAND HOPE MILLS 37-059-0002 246 MAIN STREET 213 .086 .083 .083 .080 1 DAVIE COOLEEMEE 37-063-0013 2700 NORTH DUKE STREET 211 .089 .083 .080 .077 1 DURHAM DURHAM 37-065-0099 7589 NC HWY 33-NW 207 .077 .076 .074 .074 0 EDGECOMBE LEGGETT 37-067-0022 1300 BLK. HATTIE AVENUE 214 .090 .085 .083 .082 2 FORSYTH WINSTON-SALEM 37-067-0028 6496 BAUX MOUNTAIN RD 213 .072 .069 .069 .067 0 FORSYTH WINSTON-SALEM 37-067-0030 FRATERNITY CHURCH ROAD 214 .089 .082 .081 .077 1 FORSYTH WINSTON-SALEM 37-067-1008 3656 PIEDMONT MEMORIAL 214 .091 .089 .088 .082 3 FORSYTH DRIVE WINSTON-SALEM 37-069-0001 431 S. HILLBOROUGH ST 211 .091 .076 .075 .074 1 FRANKLIN FRANKLINTON 37-075-0001 FOREST ROAD 423 SPUR 207 .082 .080 .080 .076 0 GRAHAM KLIMER 37-077-0001 WATER TREATMENT PLANT 204 .096 .082 .081 .076 1 GRANVILLE JOHN UMSTEAD HOSPITAL BUTNER 36 SITE NUMBER ADDRESS VALID DAYS VALID DAILY 8-HR MAXIMUM N0. VALUES COUNTY .>.085 1st 2nd 3rd 4th MEAS 37-081-0013 205 WILOUGHBY 164 .088 .086 .080 .080 2 GUILFORD GREENSBORO 37-087-0004 2177 SHEVILLE ROAD 213 .070 .069 .069 .069 0 HAYWOOD WAYNESVILLE 37-087-0035 TOWER BLUE RIDGE PARKWAY 200 .087 .081 .080 .079 1 HAYWOOD MILE MARKER 410 37-087-0036 GREAT SMOKY MOUNTAIN 204 .078 .077 .074 .073 0 HAYWOOD NATIONAL PARK 37-099-0005 BARNET KNOB FIRE TOWER 200 .085 .084 .083 .081 1 JACKSON 37-101-0002 1338 JACK ROAD 211 .078 .076 .073 .072 0 JOHNSTON CLAYTON 37-107-0004 CORNER HWY 70 EAST 194 .081 .080 .074 .071 0 LENOIR KINSTON 37-109-0004 1487 RIVERVIEW ROAD 208 .096 .095 .089 .082 3 LINCOLN LINCOLNTON 37-117-0001 1210 HAYES STREET 208 .076 .072 .071 .070 0 MARTIN JAMESVILLE 37-119-0041 1130 EASTWAY DRIVE 213 .103 .099 .094 .091 7 MECKLENBURG CHARLOTTE 37-119-1005 400 WESTINGHOUSE BLVD. 214 .098 .082 .081 .078 1 MECKLENBURG CHARLOTTE 37-119-1009 29 N@ MECKLENBURG CAB CO 213 .102 .095 .094 .093 8 MECKLENBURG CHARLOTTE 37-129-0002 6028 HOLLY SHELTER RD 192 .079 .076 .072 .070 0 NEW HANOVER 37-145-0003 SR NC 49 214 .079 .076 .076 .075 0 PERSON 37-147-0099 US 264 NEAR WATER TOWER 202 .081 .077 .076 .072 0 PITT FARMVILLE 37-157-0099 6371 NC 65 @ BETHANY SCHOOL 212 .088 .078 .077 .075 1 ROCKINGHAM BETHANY 37-159-0021 301 WEST ST & GOLD HILL AVE 195 .088 .087 .085 .085 5 ROWAN ROCKWELL 37-159-0022 925 N ENOCHVILLE AVE 214 .098 .096 .089 .089 7 ROWAN ENOCHVILLE 37-173-0002 CENTER STREET 207 .068 .066 .065 .063 0 SWAIN PARKS 7 REC FACILITY 37-179-0003 701 CHARLES STREET 165 .096 .095 .083 .080 2 UNION MONROE 37-183-0014 E. MILLBROOK JR HI 197 .083 .080 .080 .078 0 WAKE 3801 SPRING FOREST ROAD 37 SITE NUMBER ADDRESS VALID DAYS VALID DAILY 8-HR MAXIMUM N0. VALUES COUNTY .>.085 1st 2nd 3rd 4th MEAS 37-183-0016 201 NORTH BROAD STREET 210 .082 .075 .074 .073 0 WAKE FUQUAY-VARINA 37-199-0003 STATE HIGHWAY 128 50 .079 .077 .069 .067 0 YANCY 37-199-0004 NEW LOC MT MITCHELL 138 .077 .075 .075 .074 0 YANCEY Total Samples 8,392 48 Total Sites Sampled 42 38 Figure 5.12 Ozone: Second Highest Annual 1-Hour Average, 2006 Figure 5.13 Ozone: Mean Annual Fourth Highest 8-Hour Average, 2004-2006 39 5.6 Sulfur Dioxide Sulfur dioxide (SO2) concentrations were measured by the state and two local program agencies using EPA reference or equivalent methods. Eight SO2 monitors were active in North Carolina in 2006. Some SO2 sites are operated only every third year. We supplemented this report with one monitor that operated last in 2005, (and will next be operated in 2008), and three monitors that operated last in 2004 (and will next be operated in 2007). From the 12 sites with SO2 data obtained between 2004 and 2006, 82,161 valid hourly averages were collected. A map of the active SO2 sampling sites is presented in Figure 5.14 and a detailed summary of the data from each site is given in Table 5.7. There were no exceedances of the SO2 ambient air quality standards in 2006. The highest annual arithmetic mean was 0.005 ppm, or about 17 percent of the standard (0.03 ppm). The highest maximum 24-hour average was 0.032 ppm, about 23 percent of the standard (0.14 ppm), and the highest maximum 3-hour average was 0.082 ppm, about 16 percent of the welfare-related (secondary) standard (0.50 ppm). Apparently, the size of an urban area has little effect on the ambient concentrations of SO2 in North Carolina. Seasonal variations, such as those with CO and O3, do not appear to exist for SO2. Major source characteristics such as type, size, distribution, control devices, operating conditions and dispersion situations significantly affect the amount of SO2 in ambient air. The second highest three-hour concentrations in each county are shown in Figure 5.15. The second highest 24-hour concentrations in each county are shown in Figure 5.16. 40 Figure 5.14 Locations of Sulfur Dioxide Monitoring Sites in 2004, 2005 and 2006 Table 5.7 Sulfur Dioxide in Parts Per Million from All Sites for 2004-2006 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA THREE-HOUR MAXIMA 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 1st 2nd 1st 2nd 2006 37-013-0006 NC 306@ PCS ENTRANCE 8,039 .041 .035 .027 .024 .009 .007 .0017 BEAUFORT AURORA 37-051-1003 3625 GOLFVIEW RD 8,262 .020 .019 .012 .011 .007 .007 .0022 CUMBERLAND HOPE MILLS 37-067-0022 1300 BLK. HATTIE AVE 7,240 .090 .082 .068 .049 .022 .020 .0052 FORSYTH WINSTON-SALEM 37-117-0001 MARTIN 1210 HAYES STREET JAMESVILLE 1,259 .015 .012 .009 .009 .006 .004 .0019 37-117-0002 MARTIN 33215 US HIGHWAY 64 536 .027 .020 .019 .017 .007 .005 .0022 37-119-0041 MECKLENBURG 1130 EASTWAY DRIVE CHARLOTTE 8,532 .083 .082 .071 .064 .017 .013 .0033 37-129-0006 HIGHWAY 421 NORTH 8,107 .173 .106 .082 .065 .032 .030 .0051 NEW HANOVER WILMINGTON 37-183-0014 WAKE 3801 SPRING FOREST RD. 7,813 .031 .027 .023 .020 .007 .006 .0015 RALEIGH Total Samples 49,788 Total Sites Sampled 8 41 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA THREE-HOUR MAXIMA 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 1st 2nd 1st 2nd 2005 37-129-0002 6028 HOLLY SHELTER RD 7,992 .067 .063 .037 .033 .009 .008 .0024 NEW HANOVER CASTLE HAYNE Total Samples 7,992 Total Sites Sampled 1 2004 DAT 37-065-0099 7589 NC HWY 33-NW 7,875 .018 .017 .016 .015 .009 .008 .0020 EDGECOMBE LEGGETT 37-145-0003 PERSON STATE ROAD 1102 & NC 49 8,276 .119 .096 .095 .073 .026 .021 .0039 ROXBORO 37-173-0002 SWAIN CENTER ST/PARKS & RECREATION FACILITY 8,230 .012 .012 .011 .010 .008 .006 .0021 BRYSON CITY Total Samples 24,381 Total Sites Sampled 3 42 Figure 5.15 Sulfur Dioxide: Second Highest 3-Hour Averages in the Most Recent Year of Data from 2004, 2005 or 2006 Figure 5.16 Sulfur Dioxide: Second Highest 24-Hour Averages in the Most Recent Year of Data from 2004, 2005 or 2006 43 5.7 Nitrogen Dioxide Nitrogen dioxide (NO2) concentrations were measured using EPA reference or equivalent continuous monitors in 2006 at one local program site in Forsyth County and one local program site in Mecklenburg County. From these two sites, 14,180 hourly NO2 measurements were reported. A map of the NO2 sampling sites is presented in Figure 5.17, and a summary of the 2006 NO2 data is given in Table 5.8. Each urban area site has only a few outlying high hourly sample values that are above the standard defined for the annual arithmetic mean. The arithmetic means (Table 5.8) are about 25 percent of the standard. Figure 5.17 Location of Nitrogen Dioxide Monitoring Sites Table 5.8 Nitrogen Dioxide in Parts Per Million for 2006 SITE NUMBER ADDRESS NUM OBS ONE-HOUR MAXIMA ARITH MEAN COUNTY 1ST 2ND 37-067-0022 1300 BLK. HATTIE AVENUE 7,142 0.054 0.053 0.011 FORSYTH WINSTON-SALEM 37-119-0041 1130 EASTWAY DRIVE 7,038 0.060 0.055 0.013 MECKLENBURG CHARLOTTE Total Samples 14,180 Total Sites Sampled 2 44 5.8 Lead The state and local program agencies have not performed routine analysis of ambient lead (Pb) in North Carolina since 1982. Lead monitoring was discontinued as a result of the low measurements and a continuing decrease in the lead concentrations being reported. The decrease in ambient Pb concentrations is due to the reduction and elimination of leaded gasoline, resulting in greatly reduced lead emissions from automobiles. 5.8.1 Special Studies The most recent year of data available prior to 1996-97 was in 1990. Because the previous data were so old, the state began metals analysis at three locations in 1996. These metal sites will be relocated to other locations in future years. The purpose of these sites is to gather background information about lead and other metals. No lead sites operated in 2006. The change in analytical laboratories from the EPA‟s National Particulate Analysis Program to the state program also changed the minimum detectable levels of the method from 0.01 to 0.04 g/m3, respectively. Concentrations of most metals are below detectable limits regardless of the method used. During 1999 and 2000, a special study focusing on arsenic levels was undertaken. Lead, and other toxic metals were sampled on filters using the TSP Reference Method at selected ambient air monitoring sites, by a contract laboratory using inductively coupled plasma/mass spectrometry (ICP/MS). This method can detect sample concentrations of lead as small as 0.01 nanograms (0.00001 g) per cubic meter. Of the 526 valid samples analyzed in 1999 only 18 exceeded the Reference Method‟s detection limits. Only one sample exceeded 0.04 g/m3, and 17 others exceeded 0.01 g/m3. 45 6 Air Quality Index The Air Quality Index (AQI) was developed by the EPA to provide the public with a simple, accessible, and uniform assessment of air quality at a specific location, based on the criteria pollutants PM2.5, PM10, CO, O3 (both 1 and 8 hour values), SO2 and NO2. AQI measurements are made and reported in all U.S. metropolitan statistical areas (MSA) with a population over 350,000. Ambient concentrations for each of these seven pollutants are converted to a numerical scale ranging from 0 to 500, where 100 corresponds to the EPA primary standard for a 24-hour average (8-hour CO average, 1 and 8-hour O3 average) and 500 corresponds to a concentration associated with significant harm. The AQI is determined by the pollutant with the highest scaled concentration, and a subjective description of good, moderate, “unhealthy for sensitive groups”, “unhealthy”, very unhealthy, or hazardous is included with the report, with the descriptions corresponding to AQI values of 0-50, 51-100, 101-150, 151-200, 201-300, and 301-500, respectively. For AQI values between 101 and 500, an appropriate cautionary statement is included advising people susceptible to deleterious health effects to restrict activities and exposure to the ambient air. An AQI of 101-200 (unhealthy for sensitive groups and unhealthy) can produce mild aggravation of symptoms in susceptible persons and possible irritation in healthy persons. People with existing heart or lung ailments should reduce physical exertion and outdoor activity. The general population should reduce vigorous outdoor activity. An AQI of 201 to 300 (very unhealthy) can produce significant aggravation of symptoms and decreased exercise tolerance in persons with heart or lung disease, and a variety of symptoms in healthy persons. Elderly people and those with existing heart or lung disease should stay indoors and reduce physical activity. The general population should avoid vigorous outdoor activity. The health effects of an AQI of over 300 (hazardous) include early onset of certain diseases in addition to significant aggravation of symptoms and decreased exercise tolerance in healthy persons. The elderly and persons with existing diseases should stay indoors and avoid physical exertion. At AQI values over 400, premature death of ill and elderly persons may result, and healthy people will experience adverse symptoms that affect normal activity. Outdoor activity should be avoided. All people should remain indoors, keeping windows and doors closed, and should minimize physical exertion. 46 During summer months in North Carolina the highest air quality index value tends to be attributed to ozone, but during winter months PM2.5 predominates, except where carbon monoxide monitors are operated. In 2006, Charlotte area provided an AQI report to the public by telephone using computer- generated recorded voice announcements 24 hours daily. The AQI report also may be published by local newspapers or broadcast on radio and television stations. The Air Quality Index report is available by telephone for Charlotte area at 704-333-SMOG. We also provide an AQI Report on the North Carolina DAQ web site, (http://www.daq.state.nc.us/monitor). In this printed report, we have summarized AQI statistics for six metropolitan areas in North Carolina. Table 6.1 shows the number of days in each health category at each area. In the Ashville MSA, the AQI was not “unhealthy for sensitive groups” or “unhealthy” for any days out of 364 days monitored. Figure 6.1 shows the 2006 AQI time series for Asheville. Figure 6.2 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Asheville. In the Charlotte-Gastonia-Rock Hill MSA, the AQI was “unhealthy for sensitive groups” or “unhealthy” on 20 out of 365 days monitored. All 20 of these days occurred between May and August. Figure 6.3 shows the 2006 AQI time series for Charlotte-Gastonia-Rock Hill. Figure 6.4 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Charlotte-Gastonia-Rock Hill. In the Fayetteville MSA, the AQI was not “unhealthy for sensitive groups” or “unhealthy” for any days out of 365 days monitored. Figure 6.5 shows the 2006 AQI time series for Fayetteville. Figure 6.6 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Fayetteville. In the Greensboro-Winston-Salem-High Point MSA, the AQI was “unhealthy for sensitive groups” or “unhealthy” on 11 out of 365 days monitored. All 11 of these days occurred between March and August. Figure 6.7 shows the 2006 AQI time series for Greensboro- Winston-Salem-High Point. Figure 6.8 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Greensboro-Winston-Salem-High Point. 47 In the Raleigh-Durham-Chapel Hill MSA, the AQI was “unhealthy for sensitive groups” or “unhealthy” on three out of 365 days monitored. All three of these days occurred between June and August. Figure 6.9 shows the 2006 AQI time series for Raleigh-Durham-Chapel Hill. Figure 6.10 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Raleigh-Durham-Chapel Hill. In the Wilmington MSA, the AQI was not “unhealthy for sensitive groups” or “unhealthy” for any days out of 364 days monitored. Figure 6.11 shows the 2006 AQI time series for Wilmington. Figure 6.12 shows summaries of the numbers of days each respective pollutant was responsible for the AQI, the number of days the AQI was in each respective health category, and the percentile distribution for each health category for Wilmington. Table 6.1 Air Quality Index Category Days in the Major Metropolitan Statistical Areas, 2006 MSA STATISTICALTREATMENT GOOD MODERATE UNHEALTHY FOR SENSITIVE GROUPS UNHEALTHY Asheville actual 259 105 0 0 Charlotte actual 169 176 19 1 Fayetteville actual 242 123 0 0 Greensboro actual 174 180 10 1 Raleigh actual 199 163 3 0 Wilmington actual 310 54 0 0 48 Figure 6.1 Daily Air Quality Index Values for Asheville Figure 6.2 Daily Air Quality Index Summary for Asheville Days Per Main Pollutant 0 50 100 150 200 250 300 350 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 300 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 49 Figure 6.3 Daily Air Quality Index Values for Charlotte-Gastonia Figure 6.4 Daily Air Quality Index Summary for Charlotte-Gastonia Days Per Main Pollutant 0 50 100 150 200 250 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 20 40 60 80 100 120 140 160 180 200 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 50 Figure 6.5 Daily Air Quality Index Values for Fayetteville Figure 6.6 Daily Air Quality Index Summary for Fayetteville Days Per Main Pollutant 0 50 100 150 200 250 300 350 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 300 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 51 Figure 6.7 Daily Air Quality Index Values for Greensboro-Winston-Salem-High Point Figure 6.8 Daily Air Quality Index Summary for Greensboro-Winston-Salem-High Point Days Per Main Pollutant 0 50 100 150 200 250 300 350 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 20 40 60 80 100 120 140 160 180 200 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 52 Figure 6.9 Daily Air Quality Index Values for Raleigh-Durham-Chapel Hill Figure 6.10 Daily Air Quality Index Summary for Raleigh-Durham-Chapel Hill Days Per Main Pollutant 0 50 100 150 200 250 300 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 53 Figure 6.11 Daily Air Quality Index Values for Wilmington Figure 6.12 Daily Air Quality Index Summary for Wilmington Days Per Main Pollutant 0 50 100 150 200 250 CO NO2 O3 PM10 PM2.5 SO2 Days Per Health Category 0 50 100 150 200 250 300 350 Go o d Mo dera te UnhealthySens itive Unhealthy Very Unhealthy Hazardo us 54 7 Acid Rain 7.1 Sources Acid rain is produced when nitrate and sulfate ions from automobile and industrial sources are released into the atmosphere, undergo a reaction with moisture in the air, and are deposited as acid precipitation. Acid ions are produced when sulfur dioxide and nitrogen oxides react with water to form sulfuric acid and nitric acid. 7.2 Effects Many agricultural crops in North Carolina are sensitive to acid rain. Forests are subject to mineral loss from acid rain exposure and may also suffer root damage. Acid fogs and mists, typical in the mountains of North Carolina, can expose trees and plants to even higher acid concentrations and cause direct damage to foliage. Lakes, rivers and streams that are too acidic can impede fish and plant growth. 7.3 Monitoring Acid rain monitoring has been conducted nationally, including in North Carolina, since 1978 by the National Atmospheric Deposition Program (NADP) and the National Trends Network (NTN) which merged with NADP in 1982. In 2006, acid rain samples were collected at eight sites in North Carolina and one Tennessee site in the Great Smoky Mountains less than 10 miles from the western border of North Carolina. NADP conducts acid deposition monitoring using a wet/dry bucket type sampler. When rainfall is detected, a sensor is activated and a metal lid automatically covers and protects the dry sample, exposing the wet bucket to collect precipitation. Acidity is measured using a pH scale. The pH scale is numbered from 0 to 14, with 0 being extremely acidic and 14 being extremely basic. A substance with a pH of five is 10 times as acidic as one with a pH of six, 100 times as acidic as a substance with a pH of seven, etc. Neutral water with an equal concentration of acid and base ions has a pH of seven. The pH of vinegar is approximately 2.8, and lemon juice has a pH of about 2.3. The pH of ammonia is approximately 12. Pure water in equilibrium with the air is slightly acidic and has a pH of approximately 5.6. The measurements of pH at the North Carolina monitoring sites in 2006 ranged from 4.57 to 4.90 with a mean of 4.72. The 2006 pH annual means for North Carolina from the NADP database are presented in Figure 7.1 and Table 7.1. Table 7.1 also exhibits conductivity averages and precipitation totals for rainfall. Measured concentrations of several other chemical constituents of precipitation are given in Table 7.2. The highest pH (and the least acidic) precipitation occurred at the Sampson County site. This general area in southeastern North Carolina has the greatest numbers of animal producing farms. This 55 area has the highest emissions of ammonia, a basic gas emitted from animal wastes. Table 7.2 shows that the ammonium concentration in precipitation is the highest at the Sampson County site. Figure 7.1 Annual Mean pH Values at North Carolina NADP Sites, 2006 56 Table 7.1 pH, Conductivity in Microsiemans per Centimeter and Precipitation in Inches from the National Atmospheric Deposition Program for 2006. County Site ID Address pH Conductivity Precipitation Bertie NC03 Lewiston 4.75 11.98 54.52 Carteret NC06 Beaufort 4.72 17.61 50.20 Macon NC25 Coweeta 4.64 13.62 57.75 Rowan NC34 Piedmont Research Station 4.57 17.12 37.56 Sampson NC35 Clinton Crops Research Station 4.90 10.75 49.45 Scotland NC36 Jordan Creek 4.69 13.26 49.00 Wake NC41 Finley Farm 4.78 12.90 48.29 Yancey NC45 Mt. Mitchell 4.78 9.71 68.15 Sevier (TN) TN11 Great Smoky Mountains National Park-Elkmont 4.62 14.31 69.19 57 Table 7.2 Ion Concentrations in Milligrams per Liter (Precipitation-weighted Annual Means) from the National Atmospheric Deposition Program Data for 2006. County Site ID % Complete-ness Ca Mg K Na NH4 NO3 Cl SO4 Bertie NC03 90 0.067 0.023 0.026 0.155 0.240 0.686 0.285 1.095 Beaufort NC06 90 0.111 0.123 0.044 1.033 0.144 0.668 1.851 1.151 Macon NC25 92 0.073 0.017 0.023 0.111 0.177 0.666 0.204 1.288 Rowan NC34 96 0.112 0.025 0.084 0.112 0.346 0.958 0.243 1.722 Sampson NC35 98 0.062 0.023 0.018 0.175 0.367 0.679 0.329 1.102 Scotland NC36 92 0.082 0.025 0.021 0.167 0.237 .762 0.312 1.191 Wake NC41 96 0.082 0.021 0.042 0.118 0.415 0.805 0.233 1.385 Yancey NC45 19 0.055 0.007 0.014 0.015 0.165 0.465 0.035 0.958 Sevier (TN) TN11 88 0.106 0.016 0.031 0.047 0.247 0.814 0.091 1.421 58 8. Fine Particle Speciation 8.1 Description of pollutants The main species or constituents of fine particles are classified as nitrates, sulfates, ammonium, organic carbon, elemental carbon, and crustal components (dust). These account for 75 to 85 percent of the composition of fine particles. 8.1.1 Nitrate Ammonium nitrate (NH4NO3) is the most abundant nitrate compound, resulting from a reversible gas/particle equilibrium between ammonia gas (NH3), nitric acid gas (HNO3), and particulate ammonium nitrate. Sodium nitrate (NaNO3) is found in PM2.5 and PM10 near sea coasts and salt playas (e.g., Watson et al., 1995a) where nitric acid vapor irreversibly reacts with sea salt (NaCl). 8.1.2 Sulfate Ammonium sulfate ((NH4)2SO4), ammonium bisulfate (NH4HSO4), and sulfuric acid (H2SO4) are the most common forms of sulfate found in atmospheric particles, resulting from conversion of gases to particles as described below. These compound are water-soluble and reside almost exclusively in the PM2.5 size fraction. Sodium sulfate (Na2SO4) may be found in coastal areas where sulfuric acid has been neutralized by sodium chloride (NaCl) in sea salt. Though gypsum (Ca2SO4) and some other geological compounds contain sulfate, these are not easily dissolved in water for chemical analysis, are more abundant in PM10 than in PM2.5, and they are usually classified in the geological fraction. 8.1.3 Ammonium Ammonium sulfate ((NH4)2SO4), ammonium bisulfate (NH4HSO4), and ammonium nitrate (NH4NO3) are the most common compounds containing ammonium. 8.1.4 Organic Carbon Particulate organic carbon consists of hundreds, possibly thousands, of separate compounds with more than 20 carbon atoms. Because of this lack of molecular specificity and the semi-volatile nature of many carbon compounds with 20 to 40 carbon atoms, particulate “organic carbon” is operationally defined by the sampling and analysis method. 8.1.5 Elemental Carbon Elemental carbon is black, often called “soot.” Elemental carbon contains pure, graphitic carbon, but it also contains high molecular weight, dark-colored, non-volatile organic materials such as tar, biogenic, and coke. 59 8.1.6 Crustal Component (Fine Dust) Suspended dust consists mainly of oxides of aluminum, silicon, calcium, titanium, iron, lead and other metal oxides (Chow and Watson, 1998). The precise combination of these minerals depends on the geology of the area and industrial processes such as steel-making, smelting, mining, and cement production. Geological material is mostly in the coarse particle fraction, and typically constitutes about 50 percent of PM10 while only contributing 5 to 15 percent of PM2.5 (Chow and Watson, 1998). Lead is a toxic metal that was used for many years in products found in and around homes. Lead also is emitted into the air from motor vehicles and industrial sources. Lead may cause a range of health effects, from behavioral problems and learning disabilities, to seizures and death. The DAQ monitored lead as a federal criteria pollutant in the past (see chapter 5) until it become undetectable by the prescribed sampling method*. For these reasons we include concentration of the lead in PM2.5 in this report. 8.1.7 “Other” Speciated components. We categorize the 15 to 25 percent of PM2.5 not accounted for by nitrate, sulfate, ammonium, carbon and crustal components as “other” speciated data. For the purpose of this report “other” is not defined in any certain kind of particulate matter, but is simply the * EPA promulgated a new lead standard in 2008, and DAQ anticipates establishing a reporting network for it in 2011. result of subtracting all the other components from the total PM2.5 reported by the sampler. Among the constituents of “other” are liquid water and many trace chemical elements. 8.2 Sources Sources of fine particles include all types of combustion activities (motor vehicles, power plants, wood burning, etc.) and certain industrial processes. Other particles may be formed in the air from the chemical reactions of gases. They are indirectly formed when gases from burning fuels react with sunlight and water vapor. These can result from fuel combustion in motor vehicles, at power plants, and in other industrial processes. Particles emitted directly from a source may be either fine (less than 2.5 m) or larger (2.5 - 60 m), but particles photo-chemically formed in the atmosphere will usually be fine. Generally, larger particles have very slow settling velocities and are characterized as suspended particulate matter. Typically, fine particles originate by condensation of materials produced during combustion or atmospheric reactions. Fine particles also form from the reaction of gases or droplets in the atmosphere from sources such as power plants. These chemical reactions can occur miles from the original source of the emissions. Because fine particles can be carried long distances from their source, events such as wildfires or volcanic eruptions can raise fine particle concentrations hundreds of miles from the event. 60 PM2.5 is also produced by common indoor activities. Some indoor sources of fine particles are tobacco smoke, cooking (e.g., frying, sautéing, and broiling), burning candles or oil lamps, and operating fireplaces and fuel-burning space heaters (e.g., kerosene heaters). Particles and ozone are similar in many respects. Both can cause respiratory symptoms and other serious health problems. Fossil fuel combustion is a leading source of both pollutants. One significant difference is that particles can be a problem at any time of year, unlike ozone, which forms in warm, sunny weather and therefore tends to be seasonal in nature. 8.3 Effects The size of the particles is what is most important from a public health viewpoint. Particles larger than 10 m generally get caught in the nose and throat, never entering the lungs. Particles smaller than 10 m can get into the large upper branches just below your throat where they are caught and removed (by coughing and spitting or by swallowing). Particles smaller than 5 m can get into your bronchial tubes, at the top of the lungs; particles smaller than 2.5 m in diameter can get down into the deepest (alveolar) portions of your lungs where gas exchange occurs between the air and your blood stream, oxygen moving in and carbon dioxide moving out. These are the really dangerous particles because the deepest (alveolar) portions of the lung have no efficient mechanisms for removing them. If these particles are soluble in water, they pass directly into the blood stream within minutes. If they are not soluble in water, they are retained in the deep lung for long periods (months or years). About 60 percent of PM10 particles (by weight) have a diameter of 2.5 m or less. These are the particles that can enter the human lung directly. 8.4 Monitoring The MetOne SASS monitor measures PM2.5 mass and the chemical composition of PM2.5 (sulfates, nitrates, organic carbon, soot-like carbon and metals). This is known as PM2.5 chemical speciation. The MetOne SASS utilizes five independent channels (the Met One Super SASS utilizes eight independent channels) with spiral impactors attached directly to the filter cartridges that are arrayed in a raised carousel. Each canister has its own PM2.5 inlet and Federal Reference Method/Monitor filter holders. The PM2.5 separation is produced by a sharp cut cyclone that removes both solid and liquid coarse particles with equal efficiency without the use of impaction grease or oil. The Interagency Monitoring of Protected Visual Environments (IMPROVE) is a cooperation between federal land managers, state and local agencies and EPA to collect aerosol particulate data. IMPROVE sites use a different monitoring method. The standard IMPROVE sampler has four modules: (1) PM2.5 mass, (2) sulfate, nitrate and chloride, (3) PM2.5 quartz and (4) PM10 mass. Data are validated on a monthly basis when reports are received from the contract laboratory RTI International. NCDAQ collected data at ten sites using MetOne SASS method, the National Park Service collected at three sites during 2004 using the IMPROVE method. Figure 8.1 shows a map of all 61 these sites. Table 8.1 identifies the sites and the specific sampling methods employed at each one. Nitrate samples in 2006 are summarized in Table 8.2. The highest concentration observed was 5.71 g/m3 at Kinston. Sulfate samples in 2006 are summarized in Table 8.3. The highest concentration observed was 17.73 g/m3 at Linville. Ammonium samples in 2006 are summarized in Table 8.4. The highest concentration observed was 4.96 g/m3 at Greensboro. Organic Carbon samples in 2006 are summarized in Table 8.5. The highest concentration observed was 16.10 g/m3 at Rockwell. Elemental Carbon samples in 2006 are summarized in Table 8.6. The highest concentration observed was 3.68 g/m3 at Lexington. Crustal Component samples in 2006 are summarized in Table 8.7. The highest concentration observed was 10.20 g/m3 at Charlotte. Elemental lead samples for 2006 are summarized in Table 8.8. Out of 888 samples statewide, 34 samples exceeded 0.01 g/m3 ; 854 of these sample concentrations (96 percent) were less than 0.01 μg/m3. Twelve samples were greater than 0.014 g/m3. The highest concentration observed was 0.148 g/m3 at Lexington on Dec. 19, 2006. We were unable to find an explanation for this extremely unusual sample concentration. “Other” samples in 2006 are summarized in Table 8.9. The highest concentration observed was 70.12 g/m3 at Lexington. 62 Figure 8.1 Location of Nitrate, Sulfate, Ammonium, Organic Carbon, Elemental Carbon, Crustal component, “Other” component, Monitoring Sites 2006 Table 8.1 Fine Particle Speciation Sites Operated in North Carolina in 2006 SITE NUMBER ADDRESS METHOD COUNTY 37-011-0002 7510 BLUE RIDGE PARKWAY SPUR IMPROVE AVERY LINVILLE 37-021-0034 175 BINGHAM ROAD SASS BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET SASS CATAWBA HICKORY 37-057-0002 S.SALISBURY ST SASS DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE SASS FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD SASS GUILFORD GREENSBORO 37-087-0035 SHINING ROCK WILDERNESS IMPROVE HAYWOOD 63 SITE NUMBER ADDRESS METHOD COUNTY 37-095-9000 SWANQUARTER WILDLIFE REFUGE IMPROVE HYDE 37-107-0004 HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH SASS LENOIR KINSTON 37-119-0041 1130 EASTWAY DRIVE SASS MECKLENBURG CHARLOTTE 37-159-0021 301 WEST ST & GOLD HILL AVE SASS ROWAN ROCKWELL 37-183-0014 3801 SPRING FOREST RD SASS WAKE RALEIGH SITES OPERATED IN 12 2006 Table 8.2 Nitrate PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-011-0002 AVERY 7510 BLUE RIDGE PARKWAY SPUR 96 1.39 0.81 0.70 0.61 .209 LINVILLE 37-021-0034 175 BINGHAM ROAD 54 2.56 2.21 1.50 1.44 .625 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 5.22 3.88 3.21 2.70 .947 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 4.91 4.62 3.74 2.82 .988 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 5.28 3.23 3.16 2.42 .916 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 3.46 2.83 2.40 2.32 .729 GUILFORD GREENSBORO 37-087-0035 HAYWOOD TOWER BLUE RIDGE PARKWAY 110 1.09 0.93 0.88 0.85 .250 MILE MARKER 410 37-095-9000 SWANQUARTER 108 2.43 1.43 1.38 1.28 .386 HYDE 64 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 54 5.71 4.03 4.02 2.28 .989 KINSTON 37-119-0041 1130 EASTWAY DRIVE 118 5.59 4.70 3.63 2.67 .864 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 4.53 3.82 3.58 2.72 .873 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 5.38 2.96 2.76 2.62 1.007 WAKE RALEIGH Total Samples 893 Total Sites Sampled 12 Table 8.3 Sulfate PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-011-0002 AVERY 7510 BLUE RIDGE PARKWAY SPUR 96 17.73 15.61 12.27 10.44 4.002 LINVILLE 37-021-0034 175 BINGHAM ROAD 54 10.20 9.30 8.18 7.74 3.808 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 15.10 12.90 10.40 10.20 4.492 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 13.90 13.70 12.70 12.40 5.213 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 12.60 11.60 11.50 8.34 4.541 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 14.00 12.00 11.40 11.10 5.777 GUILFORD GREENSBORO 37-087-0035 HAYWOOD TOWER BLUE RIDGE PARKWAY 110 12.06 11.92 11.49 10.83 3.030 MILE MARKER 410 37-095-9000 SWANQUARTER 108 13.84 10.43 9.34 8.98 3.255 HYDE 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 54 10.80 8.54 7.91 7.53 3.805 KINSTON 65 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-119-0041 1130 EASTWAY DRIVE 118 14.80 12.80 11.40 11.30 4.397 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 12.10 10.90 10.70 10.60 4.722 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 9.02 9.00 7.78 7.05 3.603 WAKE RALEIGH Total Samples 893 Total Sites Sampled 12 Table 8.4 Ammonium Ion PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 2.91 2.88 2.86 2.39 1.232 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 4.35 4.13 3.83 3.80 1.653 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 4.40 4.11 3.90 3.86 1.852 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 4.29 3.84 3.69 3.39 1.716 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 43 4.96 3.94 3.29 3.19 1.904 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 54 4.40 4.15 3.26 3.15 1.515 KINSTON 37-119-0041 1130 EASTWAY DRIVE 118 4.13 4.09 3.73 3.58 1.550 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 4.09 3.92 3.70 3.45 1.649 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 4.04 3.57 3.09 2.95 1.448 WAKE RALEIGH Total Samples 579 Total Sites Sampled 9 66 Table 8.5 Organic Carbon CSN PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 15.70 9.04 8.61 7.61 4.649 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 11.00 10.50 10.00 8.90 5.649 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 60 12.60 12.30 10.70 9.29 5.635 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 10.30 9.05 8.96 7.80 4.613 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 45 10.30 9.11 7.70 7.30 4.741 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 56 8.69 7.66 5.72 6.57 3.676 KINSTON 37-119-0041 1130 EASTWAY DRIVE 115 11.50 10.00 9.57 9.51 4.962 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 16.10 10.30 9.67 8.81 5.102 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 9.21 8.58 8.15 7.45 4.556 WAKE RALEIGH Total Samples 580 Total Sites Sampled 9 Table 8.6 Elemental Carbon CSN PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 1.14 1.07 .96 .86 .502 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 58 2.41 2.27 2.09 1.69 .840 CATAWBA HICKORY 67 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-057-0002 S.SALISBURY ST 60 3.68 2.06 1.90 1.71 .759 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 2.11 1.62 1.58 1.53 .658 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 45 1.36 1.25 1.04 1.01 .545 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 56 1.01 .70 .69 .67 .317 KINSTON 37-119-0041 1130 EASTWAY DRIVE 115 2.79 1.91 1.90 1.84 .693 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 1.74 1.38 1.08 1.02 .554 ROCKWELL 37-183-0014 3801 SPRING FOREST RD 77 1.77 1.69 1.68 1.60 .653 WAKE RALEIGH Total Samples 580 Total Sites Sampled 9 Table 8.7 Crustal Component PM2.5 - Micrograms/Cubic Meter (LC) for 2006 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th 37-021-0034 175 BINGHAM ROAD 54 6.01 1.41 1.40 1.22 .537 BUNCOMBE ASHEVILLE 37-035-0004 1650 1ST STREET 56 1.04 .99 .98 .80 .421 CATAWBA HICKORY 37-057-0002 S.SALISBURY ST 59 3.91 1.27 1.26 1.04 .510 DAVIDSON LEXINGTON 37-067-0022 1300 BLK HATTIE AVE 55 3.75 .82 .66 .65 .412 FORSYTH WINSTON-SALEM 37-081-0013 205 WILOUGHBY BLVD 45 3.85 .81 .79 .78 .450 GUILFORD GREENSBORO 37-107-0004 LENOIR HIGHWAY 70 EAST AND HIGHWAY 58 SOUTH 56 4.11 .98 .81 .79 .378 68 SITE NUMBER ADDRESS NUM OBS 24-HOUR MAXIMA ARITH MEAN COUNTY 1st 2nd 3rd 4th KINSTON 37-119-0041 1130 EASTWAY DRIVE 116 10.27 4.31 2.24 1.90 .608 MECKLENBURG CHARLOTTE 37-159-0021 ROWAN 301 WEST ST & GOLD HILL AVE 60 3.66 1.02 .9 |
OCLC number | 34083482 |