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Published January 2, 1998 | public
Journal Article Metadata-only

Hydrogen Radicals, Nitrogen Radicals, and the Production of O_3 in the Upper Troposphere

Wennberg, P. O. ORCID icon
Hanisco, T. F. ORCID icon
Jaeglé, L.
Jacob, D. J. ORCID icon
Hintsa, E. J.
Lanzendorf, E. J.
Anderson, J. G.
Gao, R.-S.
Keim, E. R.
Donnelly, S. G.
Del Negro, L. A.
Fahey, D. W.
McKeen, S. A.
Salawitch, R. J.
Webster, C. R.
May, R. D.
Herman, R. L.
Proffitt, M. H.
Margitan, J. J.
Atlas, E. L. ORCID icon
Schauffler, S. M.
Flocke, F.
McElroy, C. T.
Bui, T. P.

Abstract

The concentrations of the hydrogen radicals OH and HO2in the middle and upper troposphere were measured simultaneously with those of NO, O_3, CO, H_(2)O, CH_4, non-methane hydrocarbons, and with the ultraviolet and visible radiation field. The data allow a direct examination of the processes that produce O_3 in this region of the atmosphere. Comparison of the measured concentrations of OH and HO_2 with calculations based on their production from water vapor, ozone, and methane demonstrate that these sources are insufficient to explain the observed radical concentrations in the upper troposphere. The photolysis of carbonyl and peroxide compounds transported to this region from the lower troposphere may provide the source of HO_x required to sustain the measured abundances of these radical species. The mechanism by which NO affects the production of O_3 is also illustrated by the measurements. In the upper tropospheric air masses sampled, the production rate for ozone (determined from the measured concentrations of HO_2 and NO) is calculated to be about 1 part per billion by volume each day. This production rate is faster than previously thought and implies that anthropogenic activities that add NO to the upper troposphere, such as biomass burning and aviation, will lead to production of more O_3 than expected.

Additional Information

© 1998 American Association for the Advancement of Science. Received 15 October 1997; accepted 18 November 1997. We thank the pilots and ground crew of the NASA ER-2 Aircraft, and the STRAT mission scientists (S. Wofsy, Harvard University, and P. Newman, NASA Goddard Space Flight Center) for their help obtaining this data set. K. Wolfe, J. Barrilleaux, E. Condon, S. Hipskind, M. Craig, S. Gaines, J. Goosby, and O. Allison provided logistical support for this field effort. We acknowledge R. Lueb, V. Stroud, and H. Krapfl for assistance with the whole-air sampler data set. A portion of the research described in this paper was carried out by the Jet Propulsion Laboratory, California Institute of Technology, under contract with NASA. Partial support for analysis of the STRAT data set was provided by a grant from the National Science Foundation (ATM 9612282). The STRAT program was supported by NASA through the Upper Atmosphere Research Program, the Atmospheric Chemistry Modeling and Analysis Program, and by the Atmospheric Effects of Aviation Project. We thank the officers of these programs, M. Kurylo, H. Wesoky, J. Kaye, R. Friedl, R. Kawa, D. Peterson, and P. DeCola, for support.

Additional details

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August 22, 2023
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October 26, 2023