Emission transport, chemistry and rainout of the sulfur species DMS, S
O2 and sulfate are calculated on-line with the meteorology in a global
atmospheric circulation model. The model simulates the main component
s of the hydrological cycle, including the liquid water content of clo
uds, and hence it allows an explicit treatment of cloud transformation
processes and precipitation scavenging. The importance of the differe
nt oxidation pathways of DMS and SO2 is estimated. About 2/3 of the su
lfate is produced within clouds, with H2O2 being the most efficient pa
thway (59%) and with a minor contribution due to oxidation with O-3 (7
%). Predicted atmospheric surface concentrations of SO2 and sulfate an
d the deposition fluxes are compared with the observations. Over most
parts of the globe the agreement between simulated and observed annual
averages is within a factor of 2. A significant underestimate of the
simulated sulfate concentrations was found in high latitudes in winter
. This bias may be attributed to a too slow oxidation in clouds. The c
alculated global mean turn-over times for DMS (2.2 d), SO2 (1.6 d) and
sulfate (4.4 d) are within the range of previous estimates.