A Millennium Symposium on Atmospheric Chemistry: Past, Present, and Future of Atmospheric Chemistry

2.2

Atmospheric oxidation, ozone production, and their dependence on nitrogen oxides and radical production

William H. Brune, Penn State University, University Park, PA

The hydroxyl radical, OH, drives atmospheric oxidation by reacting with chemicals emitted from Earth's surface, thus creating new chemicals that are more easily scavenged and removed by aerosols, clouds, and rain. In the oxidation process, the hydroperoxyl radical, HO2, is created. Its reaction with nitric oxide, NO, leads to ozone production. Both atmospheric oxidation (OH abundance) and ozone production initially increase as NO is added to the atmosphere, but then decrease as more NO is added. The peak value of both atmospheric oxidation and ozone production depends not only on NO, but also on the production rate of the sum of OH and HO2, called HOx.

Recent atmospheric chemistry field studies included measurements of a large suite of meteorological variables and chemical species, including the hydroxyl radical, the hydroperoxyl radical, and nitric oxide. The NO levels and HOx production rates varied widely for the sampled environments, which include air in remote Pacific Ocean troposphere, the upper troposphere and lower stratosphere at high latitudes, a moderately rural forest, and a polluted city. With observations in these diverse environments, we can examine the fundamental relationships among atmospheric oxidation, ozone production, NO, and HOx production. This examination involves both the comparison of observations to photochemical models and the determination of the functional dependence of the observed OH, HO2, and ozone production on NOx.    

Session 2, Present Work in Atmospheric Chemistry
Monday, 15 January 2001, 1:30 PM-2:45 PM

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