Exploring Oxidation in the Remote Free Troposphere: Insights From Atmospheric Tomography (ATom)
| Autor: | T. P. Bui, T. B. Ryerson, Chelsea R. Thompson, Bruce C. Daube, Thomas F. Hanisco, Roisin Commane, R. A. Hannun, Hannah M. Allen, J. A. Neuman, James W. Elkins, J. M. St Clair, John D. Crounse, Colm Sweeney, Patrick R. Veres, D. O. Miller, Fred L. Moore, Michelle J. Kim, William H. Brune, Glenn M. Wolfe, Julie M. Nicely, Alex P. Teng, Jeff Peischl, Eric C. Apel, Paul O. Wennberg, A. B. Thames, Glenn S. Diskin, Kirk Ullmann, Kathryn McKain, Eric J. Hintsa, Donald R. Blake, J. P. DiGangi, Rebecca S. Hornbrook, Samuel R. Hall |
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| Rok vydání: | 2020 |
| Předmět: |
Atmospheric Science
010504 meteorology & atmospheric sciences Planetary boundary layer Atmospheric sciences 01 natural sciences Methane Troposphere Atmosphere chemistry.chemical_compound Geophysics Altitude Hydroperoxyl chemistry Space and Planetary Science Atmospheric chemistry Greenhouse gas Earth and Planetary Sciences (miscellaneous) 0105 earth and related environmental sciences |
| Zdroj: | Journal of Geophysical Research: Atmospheres. 125 |
| ISSN: | 2169-8996 2169-897X |
| Popis: | Earth's atmosphere oxidizes the greenhouse gas methane and other gases, thus determining their lifetimes and oxidation products. Much of this oxidation occurs in the remote, relatively clean free troposphere above the planetary boundary layer, where the oxidation chemistry is thought to be much simpler and better understood than it is in urban regions or forests. The NASA airborne Atmospheric Tomography study (ATom) was designed to produce cross sections of the detailed atmospheric composition in the remote atmosphere over the Pacific and Atlantic Oceans during four seasons. As part of the extensive ATom data set, measurements of the atmosphere's primary oxidant, hydroxyl (OH), and hydroperoxyl (HO₂) are compared to a photochemical box model to test the oxidation chemistry. Generally, observed and modeled median OH and HO₂ agree to with combined uncertainties at the 2σ confidence level, which is ~±40%. For some seasons, this agreement is within ~±20% below 6 km altitude. While this test finds no significant differences, OH observations increasingly exceeded modeled values at altitudes above 8 km, becoming ~35% greater, which is near the combined uncertainties. Measurement uncertainty and possible unknown measurement errors complicate tests for unknown chemistry or incorrect reaction rate coefficients that would substantially affect the OH and HO₂ abundances. Future analysis of detailed comparisons may yield additional discrepancies that are masked in the median values. |
| Databáze: | OpenAIRE |
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