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dc.contributor.authorNakamura, Y.
dc.contributor.authorLeblanc, F.
dc.contributor.authorTerada, N.
dc.contributor.authorHiruba, S.
dc.contributor.authorMurata, I.
dc.contributor.authorNakagawa, H.
dc.contributor.authorSakai, S.
dc.contributor.authorAoki, S.
dc.contributor.authorPiccialli, A.
dc.contributor.authorWillame, Y.
dc.contributor.authorNeary, L.
dc.contributor.authorVandaele, A.C.
dc.contributor.authorMurase, K.
dc.contributor.authorKataoka, R.
dc.date2023
dc.date.accessioned2023-12-09T09:08:06Z
dc.date.available2023-12-09T09:08:06Z
dc.identifier.urihttps://orfeo.belnet.be/handle/internal/11197
dc.descriptionPrecipitation of solar energetic particles (SEPs) into planetary atmospheres causes changes in atmospheric chemical composition through ionization, dissociation, and excitation of atmospheric molecules. In contrast to the terrestrial atmosphere, where depletion of ozone in the polar mesosphere has been studied by observations and models for decades, there have been no studies on the effects of SEPs on the neutral chemical composition of Mars' present-day atmosphere. This study provided the first estimate of the impacts of SEPs on neutral chemical composition in the present-day Martian atmosphere coupling a Monte Carlo model and a one-dimensional photochemical model. Our results showed that ozone density in the Martian atmosphere might decrease in the altitude range of 20–60 km with a factor 10 maximum enhancement occurring at 40 km during a Halloween-class SEP event due to an enhanced concentration of HOx. The depletion of ozone occurred in the altitude range of 20–60 km, corresponding to the penetration of protons with an energy range of 4.6–46 MeV. Such ozone depletion should be detected by Trace Gas Orbiter/Nadir and Occultation for MArs Discovery during intense SEP event. A 75\% depletion of the ozone density at 40 km can be expected during SEP events occurring once in every 1 year. Therefore, ozone concentration in the Martian atmosphere might sufficiently decrease during a SEP event as on Earth, but through different chemical pathways driven by CO2 ionization and CO recombination catalytic cycle.
dc.languageeng
dc.titleNumerical Prediction of Changes in Atmospheric Chemical Compositions During a Solar Energetic Particle Event on Mars
dc.typeArticle
dc.subject.frascatiPhysical sciences
dc.audienceScientific
dc.subject.freeMars
dc.subject.freesolar energetic particle
dc.subject.freephotochemistry
dc.subject.freeozone
dc.subject.freeTGO/NOMAD
dc.source.titleJournal of Geophysical Research: Space Physics
dc.source.volume128
dc.source.issue12
dc.source.pagee2022JA031250
Orfeo.peerreviewedYes
dc.identifier.doi10.1029/2022JA031250
dc.identifier.url


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