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Published in

European Geosciences Union, Atmospheric Chemistry and Physics, 18(12), p. 8679-8686, 2012

DOI: 10.5194/acp-12-8679-2012

IOP Publishing, Environmental Research Letters, 4(8), p. 045010, 2013

DOI: 10.1088/1748-9326/8/4/045010

European Geosciences Union, Atmospheric Chemistry and Physics Discussions, 6(12), p. 14747-14769

DOI: 10.5194/acpd-12-14747-2012

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Influence of a Carrington-like event on the atmospheric chemistry, temperature and dynamics: revised

Journal article published in 2013 by M. Calisto, P. T. Verronen, I. Usoskin ORCID, E. Rozanov, T. Peter
This paper is made freely available by the publisher.
This paper is made freely available by the publisher.

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Abstract

Abstract. We have modeled the atmospheric impact of a major solar energetic particle event similar in intensity to what is thought of the Carrington Event of 1–2 September 1859. Ionization rates for the August 1972 solar proton event, which had an energy spectrum comparable to the Carrington Event, were scaled up in proportion to the fluence estimated for both events. We have assumed such an event to take place in the year 2020 in order to investigate the impact on the modern, near future atmosphere. Effects on atmospheric chemistry, temperature and dynamics were investigated using the 3-D Chemistry Climate Model SOCOL v2.0. We find significant responses of NOx, HOx, ozone, temperature and zonal wind. Ozone and NOx have in common an unusually strong and long-lived response to this solar proton event. The model suggests a 3-fold increase of NOx generated in the upper stratosphere lasting until the end of November, and an up to 10-fold increase in upper mesospheric HOx. Due to the NOx and HOx enhancements, ozone reduces by up to 60–80% in the mesosphere during the days after the event, and by up to 20–40% in the middle stratosphere lasting for several months after the event. Total ozone is reduced by up to 20 DU in the Northern Hemisphere and up to 10 DU in the Southern Hemisphere. Free tropospheric and surface air temperatures show a significant cooling of more than 3 K and zonal winds change significantly by 3–5 m s−1 in the UTLS region. In conclusion, a solar proton event, if it took place in the near future with an intensity similar to that ascribed to of the Carrington Event of 1859, must be expected to have a major impact on atmospheric composition throughout the middle atmosphere, resulting in significant and persistent decrease in total ozone.