ROMA1 (Cape Romain NWR, SC, Lat. 32.941, Long. -79.6572, Alt. 4.7)          Print-Friendly Version         Print-Friendly Version (B&W)

Based on the regional haze rule version 2, 5 years of complete aerosol data are available in Cape Romain NWR during the baseline period of 2000 - 2004. As shown in Figure 1, the overall average total light extinction coefficient (Bext) is 84.5 Mm^-1 (Visual Range ~  59 Km; Deciview ~ 20). The average PM_2.5 mass concentration is 9.0 mg/m³. The average contributions of the major aerosol components to Cape Romain haze are particulate sulfate 55.2%, nitrate 5.7%, organic matter (OMC) 14.5%, elemental carbon (light absorbing carbon, LAC) 4.6%, fine soil 0.6%, sea salt 1.5%, and coarse mass (CM) 3.8%. 

Bext = 84.5 Mm^-1

Figure 1 Average contributions of major aerosol chemical components to light extinction (Based on data available in 2000-2004)    (B&W)

Figure 2 Average contributions of major aerosol chemical components to light extinction in 20% best, middle 60% and 20% worst days (Based on data available in 2000-2004)  (Data Table)    (B&W)

As Figure 2 indicates, the average light extinction coefficient during the 20% worst days is 147.3 Mm^-1, which is about 3.5 times of the value of 42.4 Mm^-1 during the 20% best days and 1.9 times of the value of 76.9 Mm^-1 during the middle 60% days. Sulfate is the largest aerosol contributor to light extinction during the 20% worst days, with a contribution of  ~ 66%. OMC also contributes about 16% to light extinction during the 20% worst visibility days.

Figure 3 suggests that the highest occurrence of the 20% worst days happened in July, in which ~ 45% of the sampling days are the 20% haziest days at Cape Romain. As shown in Figure 4, in the 20% worst visibility days, sulfate is the largest aerosol contributor to haze throughout the year, with a contribution from ~ 40% in the first quarter to ~ 75% in the third quarter. OMC also contributes ~23-36% during the 20% worst days in the winter and spring (January to April, November to December).

Figure 3 Percentage of sampling days that are 20% worst days in each month (Based on data available in 2000-2004)  (Data Table)    (B&W)

Figure 4 Average contributions of major aerosol chemical components to light extinction during 20% worst days in each month (Based on data available in 2000-2004)  (Data Table)    (B&W)

List of Tables:

1. Number of measurements available in each month during 2000-2004

2. Average light extinction coefficients (1/Mm) and mass concentrations (mg/m³) of the major aerosol chemical components in 20% best, middle 60% and 20% worst days based on data available during 2000-2004

3. Average light extinction coefficients (1/Mm) and percentage contributions to the aerosol light extinction coefficients (without Rayleigh scattering) of the major aerosol chemical components in 20% best, middle 60%, and 20% worst days based on data available during 2000-2004

4. Percentage of worst days happened in each month based on data available during 2000-2004

5. Average light extinction coefficients (1/Mm) of the major aerosol chemical components during the 20% worst days in each month based on data available during 2000-2004

6. Average light extinction coefficients (1/Mm) of the major aerosol chemical components in each month based on all data available during 2000-2004

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