The effectiveness of N2O in depleting stratospheric ozone

Recently, it was shown that of the ozone‐depleting substances currently emitted, N2O emissions (the primary source of stratospheric NOx) dominate, and are likely to do so throughout the 21st century. To investigate the links between N2O and NOx concentrations, and the effects of NOxon ozone in a cha...

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Published inGeophysical research letters Vol. 39; no. 15; pp. L15806 - n/a
Main Authors Revell, Laura E., Bodeker, Greg E., Smale, Dan, Lehmann, Ralph, Huck, Petra E., Williamson, Bryce E., Rozanov, Eugene, Struthers, Hamish
Format Journal Article
LanguageEnglish
Published Washington, DC Blackwell Publishing Ltd 16.08.2012
American Geophysical Union
John Wiley & Sons, Inc
Subjects
Atmosphere
Atmospheric sciences
CCM
Climate change
Earth
Earth sciences
Earth, ocean, space
Exact sciences and technology
nitrous oxide
NOx
ozone
stratosphere
depletion
Carbon dioxide
concentration
cycles
Climate models
climate
ozone
chlorine
greenhouse gas
cooling
atmospheric circulation
Nitrogen dioxide
Nitrogen protoxide
oxygen
stratosphere
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Summary:Recently, it was shown that of the ozone‐depleting substances currently emitted, N2O emissions (the primary source of stratospheric NOx) dominate, and are likely to do so throughout the 21st century. To investigate the links between N2O and NOx concentrations, and the effects of NOxon ozone in a changing climate, the evolution of stratospheric ozone from 1960 to 2100 was simulated using the NIWA‐SOCOL chemistry‐climate model. The yield of NOx from N2O is reduced due to stratospheric cooling and a strengthening of the Brewer‐Dobson circulation. After accounting for the reduced NOx yield, additional weakening of the primary NOxcycle is attributed to reduced availability of atomic oxygen, due to a) stratospheric cooling decreasing the atomic oxygen/ozone ratio, and b) enhanced rates of chlorine‐catalyzed ozone loss cycles around 2000 and enhanced rates of HOx‐induced ozone depletion. Our results suggest that the effects of N2O on ozone depend on both the radiative and chemical environment of the upper stratosphere, specifically CO2‐induced cooling of the stratosphere and elevated CH4 emissions which enhance HOx‐induced ozone loss and remove the availability of atomic oxygen to participate in NOx ozone loss cycles. Key Points NOx‐induced ozone destruction slows through the 21st century Due to chemical, radiative and dynamical changes in the stratosphere The effectiveness of N2O as an ODS is weakened by elevated CH4 concentrations
Bibliography:istex:E000ECF6C34631CB513699F6A69A830F3D635EAA
ArticleID:2012GL052143
ark:/67375/WNG-CHSR2J4B-H
ISSN:0094-8276
1944-8007
1944-8007
DOI:10.1029/2012GL052143