OCS photolytic isotope effects from first principles: sulfur and carbon isotopes, temperature dependence and implications for the stratosphere

OCS photolytic isotope effects from first principles: sulfur and carbon isotopes, temperature dependence and implications for the stratosphere

The isotopic fractionation in OCS photolysis is studied theoretically from first principles. UV absorption cross sections for OCS, OC33S, OC34S, OC36S and O13CS are calculated using the time-depedent quantum mechanical formalism and a recently developed ab-initio description of the photodissociation...

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Bibliographic Details
Published in:Atmospheric chemistry and physics Vol. 13; no. 3; pp. 1511 - 1520
Main Authors: Schmidt, J. A, Johnson, M. S, Hattori, S, Yoshida, N, Nanbu, S, Schinke, R
Format: Journal Article
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 06-02-2013
Copernicus Publications
Subjects:
Absorption cross sections
Analysis
Fractionation
Isotope effect
Mathematical models
Middle atmosphere
Photodissociation
Photolysis
Stratosphere
Sulfur compounds
Wavelengths
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Summary:The isotopic fractionation in OCS photolysis is studied theoretically from first principles. UV absorption cross sections for OCS, OC33S, OC34S, OC36S and O13CS are calculated using the time-depedent quantum mechanical formalism and a recently developed ab-initio description of the photodissociation of OCS which takes into account the lowest four singlet and lowest four triplet electronic states. The calculated isotopic fractionations as a function of wavelength are in good agreement with recent measurements by Hattori et al. (2011) and indicate that photolysis leads to only a small enrichment of 34S in the remaining OCS. The photodissociation dynamics provide strong evidence that the photolysis quantum yield is unity at all wavelengths for atmospheric UV excitation, for all isotopologues. A simple stratospheric model is constructed taking into account the main sink reactions of OCS and it is found that overall stratospheric removal slightly favors light OCS in constrast to the findings of Leung et al. (2002). These results show, based on isotopic considerations, that OCS is an acceptable source of background stratosperic sulfate aerosol in agreement with a recent model study of of Brühl et al. (2012). The 13C isotopic fractionation due to photolysis of OCS in the upper stratosphere is significant and will leave a clear signal in the remaining OCS making it a candidate for tracing using the ACE-FTS and MIPAS data sets.
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ISSN:1680-7324
1680-7316
1680-7324
DOI:10.5194/acp-13-1511-2013