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dc.contributor.authorKhosravi, R.
dc.contributor.authorBrasseur, G.
dc.contributor.authorSmith, A.
dc.contributor.authorRusch, D.
dc.contributor.authorWalters, S.
dc.contributor.authorChabrillat, S.
dc.contributor.authorKockarts, G.
dc.date2002
dc.date.accessioned2017-05-03T12:37:05Z
dc.date.available2017-05-03T12:37:05Z
dc.identifier.urihttps://orfeo.belnet.be/handle/internal/5213
dc.descriptionWe have used the improved NCAR interactive 2-D model (SOCRATES) to investigate the chemical and thermal response of the mesosphere to composition changes from the preindustrial era (∼1850) to the present, to doubling the CO2 concentration, and to the 11-year solar flux variability. The calculations show that all regions in the model mesosphere have cooled relative to the preindustrial times. The mesopause region has cooled by ∼5 K and the winter pole by up to 9 K near 60 km. Ozone mixing ratio has decreased by about 5% in the lower mesosphere and by about 30% near the summer mesopause region (caused by a dramatic increase in [OH]). Doubling the CO2 abundance cools the whole mesosphere by about 4-16 K and has a complicated effect on O3, which exhibits an alternating increase/decrease behavior from the lower mesosphere up to the mesopause region. Similar results are obtained, in both magnitude and structure, for the O3 response to a decrease in solar UV flux. Similarities are also found in the response of T, OH, and H to these two perturbations. These results lead to the conclusion that the long-term increase in the well-mixed greenhouse gases, in particular CO 2, alters the thermal structure and chemical composition of the mesosphere significantly and that these anthropogenic effects are of the same magnitude as the effects associated with the 11-year solar cycle. Thus, the difference in the timescales involved suggests that the anthropogenic signal over periods of typically 10 years is smaller than the signal generated by the 11-year solar variability. Finally, analysis of the results from a simulation of the combined perturbations (2 × CO2 + 11-year solar variability) shows that, for the most part, the solar variability does not interact with increasing CO2 and vice versa; that is, the two effects are additive.
dc.languageeng
dc.titleResponse of the mesosphere to human-induced perturbations and solar variability calculated by a 2-D model
dc.typeArticle
dc.subject.frascatiEarth and related Environmental sciences
dc.audienceScientific
dc.subject.freeAtmospheric chemistry
dc.subject.freeAtmospheric composition
dc.subject.freeCarbon dioxide
dc.subject.freeComputer simulation
dc.subject.freeGreenhouse effect
dc.subject.freeOzone
dc.subject.freeSolar radiation
dc.subject.freeUltraviolet radiation
dc.subject.freechemical composition
dc.subject.freegreenhouse gas
dc.subject.freehuman activity
dc.subject.freemesosphere
dc.subject.freeozone
dc.subject.freeperturbation
dc.subject.freetimescale
dc.subject.freeultraviolet radiation
dc.source.titleJournal of Geophysical Research: Atmospheres
dc.source.volume107
dc.source.issue18
dc.source.pageA4358
Orfeo.peerreviewedYes
dc.identifier.doi10.1029/2001JD001235
dc.identifier.scopus2-s2.0-33646500321


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