Analysis of regional budgets of sulfur species modeled for the COSAM exercise

Journal Article (Academic article)

The COSAM intercomparison exercise (comparison of large-scale sulfur models) was organized to compare and evaluate the performance of global sulfur cycle models. Eleven models participated, and from these models the simulated surface concentrations, vertical profiles and budget terms were submitted. This study focuses on simulated budget terms for the sources and sinks of SO2 and sulfate in three polluted regions in the Northern Hemisphere, i.e., eastern North America, Europe, and Southeast Asia. Qualitatively, features of the sulfur cycle are modeled quite consistently between models, such as the relative importance of dry deposition as a removal mechanism for SO2, the importance of aqueous phase oxidation over gas phase oxidation for SO2, and the importance of wet over dry deposition for removal of sulfate aerosol. Quantitatively, however, models may show large differences, especially for cloud-related processes, i.e., aqueous phase oxidation of SO2 and sulfate wet deposition. In some cases a specific behavior can be related to the treatment of oxidants for aqueous phase SO2 oxidation, or the vertical resolution applied in models. Generally, however, the differences between models appear to be related to simulated cloud (micro-)physics and distributions, whereas differences in vertical transport efficiencies related to convection play an additional role. The estimated sulfur column burdens, lifetimes and export budgets vary between models by about a factor of 2 or 3. It can be expected that uncertainties in related effects which are derived from global sulfur model calculations, such as direct and indirect climate forcing estimates by sulfate aerosol, are at least of similar magnitude

Duke Authors

Cited Authors

  • Roelofs, GJ; Kasibhatla, P; Barrie, L; Bergmann, D; Bridgeman, C; Chin, M; Christensen, J; Easter, R; Feichter, J; Jeuken, A; Kjellstrom, E; Koch, D; Land, C; Lohmann, U; Rasch, P

Published Date

  • 2001

Published In

  • Tellus B, Chem. Phys. Meteorol. (Sweden)

Volume / Issue

  • 53B / 5

Start / End Page

  • 673 - 694