TY - JOUR
T1 - An elevated reservoir of air pollutants over the Mid-Atlantic States during the 2011 DISCOVER-AQ campaign
T2 - Airborne measurements and numerical simulations
AU - He, Hao
AU - Loughner, Christopher P.
AU - Stehr, Jeffrey W.
AU - Arkinson, Heather L.
AU - Brent, Lacey C.
AU - Follette-Cook, Melanie B.
AU - Tzortziou, Maria A.
AU - Pickering, Kenneth E.
AU - Thompson, Anne M.
AU - Martins, Douglas K.
AU - Diskin, Glenn S.
AU - Anderson, Bruce E.
AU - Crawford, James H.
AU - Weinheimer, Andrew J.
AU - Lee, Pius
AU - Hains, Jennifer C.
AU - Dickerson, Russell R.
N1 - Funding Information:
The DISCOVER-AQ campaign is supported by the National Aeronautics and Space Administration (NASA) . We thank Maryland Department of the Environment for the support to the UMD RAMMPP program. We thank Dr. Ronald C. Cohen (University of California, Berkeley) for providing TD-LIF NO 2 measurements. This research was supported by NASA Ozone Monitoring Instrument (OMI) Team and NASA Air Quality Applied Science Team (AQAST) grants NNX11AK34G , NNX12AI18G and NNX10AQ79G . The authors thank two anonymous reviewers for helpful suggestions.
PY - 2013/11
Y1 - 2013/11
N2 - During a classic heat wave with record high temperatures and poor air quality from July 18 to 23, 2011, an elevated reservoir of air pollutants was observed over and downwind of Baltimore, MD, with relatively clean conditions near the surface. Aircraft and ozonesonde measurements detected ~120ppbv ozone at 800m altitude, but ~80ppbv ozone near the surface. High concentrations of other pollutants were also observed around the ozone peak: ~300ppbv CO at 1200m, ~2ppbv NO2 at 800m, ~5ppbv SO2 at 600m, and strong aerosol optical scattering (2×10-4m-1) at 600m. These results suggest that the elevated reservoir is a mixture of automobile exhaust (high concentrations of O3, CO, and NO2) and power plant emissions (high SO2 and aerosols). Back trajectory calculations show a local stagnation event before the formation of this elevated reservoir. Forward trajectories suggest an influence on downwind air quality, supported by surface ozone observations on the next day over the downwind PA, NJ and NY area. Meteorological observations from aircraft and ozonesondes show a dramatic veering of wind direction from south to north within the lowest 5000m, implying that the development of the elevated reservoir was caused in part by the Chesapeake Bay breeze. Based on in situ observations, CMAQ forecast simulations with 12km resolution overestimated surface ozone concentrations and failed to predict this elevated reservoir; however, CMAQ research simulations with 4km and 1.33km resolution more successfully reproduced this event. These results show that high resolution is essential for resolving coastal effects and predicting air quality for cities near major bodies of water such as Baltimore on the Chesapeake Bay and downwind areas in the Northeast.
AB - During a classic heat wave with record high temperatures and poor air quality from July 18 to 23, 2011, an elevated reservoir of air pollutants was observed over and downwind of Baltimore, MD, with relatively clean conditions near the surface. Aircraft and ozonesonde measurements detected ~120ppbv ozone at 800m altitude, but ~80ppbv ozone near the surface. High concentrations of other pollutants were also observed around the ozone peak: ~300ppbv CO at 1200m, ~2ppbv NO2 at 800m, ~5ppbv SO2 at 600m, and strong aerosol optical scattering (2×10-4m-1) at 600m. These results suggest that the elevated reservoir is a mixture of automobile exhaust (high concentrations of O3, CO, and NO2) and power plant emissions (high SO2 and aerosols). Back trajectory calculations show a local stagnation event before the formation of this elevated reservoir. Forward trajectories suggest an influence on downwind air quality, supported by surface ozone observations on the next day over the downwind PA, NJ and NY area. Meteorological observations from aircraft and ozonesondes show a dramatic veering of wind direction from south to north within the lowest 5000m, implying that the development of the elevated reservoir was caused in part by the Chesapeake Bay breeze. Based on in situ observations, CMAQ forecast simulations with 12km resolution overestimated surface ozone concentrations and failed to predict this elevated reservoir; however, CMAQ research simulations with 4km and 1.33km resolution more successfully reproduced this event. These results show that high resolution is essential for resolving coastal effects and predicting air quality for cities near major bodies of water such as Baltimore on the Chesapeake Bay and downwind areas in the Northeast.
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U2 - 10.1016/j.atmosenv.2013.11.039
DO - 10.1016/j.atmosenv.2013.11.039
M3 - Article
AN - SCOPUS:84890814516
SN - 1352-2310
VL - 85
SP - 18
EP - 30
JO - Atmospheric Environment
JF - Atmospheric Environment
ER -