Add to ORKGThe sulphur cycle plays fundamental roles in the chemistry and climate of Venus. Thermodynamic equilibrium chemistry at the surface of Venus favours the production of carbonyl sulphide and to a lesser extent sulphur dioxide. These gases are transported to the middle atmosphere by the Hadley circulation cell. Above the cloud top, a sulphur oxidation cycle involves conversion of carbonyl sulphide into sulphur dioxide, which is then transported further upwards. A significant fraction of this sulphur dioxide is subsequently oxidized to sulphur trioxide and eventually reacts with water to form sulphuric acid. Because the vapour pressure of sulphuric acid is low, it readily condenses and forms an upper cloud layer at altitudes of 60–70 km, and an...
International audienceVenus' global-scale cloud and haze layers are composed of complexes of sulfuri...
International audienceVenus' global-scale H2SO4 cloud and haze layers form via the combination of SO...
Venus' atm. is 96.5% CO_2 and 3.5% N_2 with trace abundances of SO_2, OCS, H_2O, HCl, HF, and HBr, a...
The sulphur cycle plays fundamental roles in the chemistry and climate of Venus. Thermodynamic equil...
P.B.R. thanks the Simons Foundation for funding (SCOL awards 599634). P.W. acknowledges funding from...
Sulfur compounds have been observed in the atmospheres of a number of planetary bodies in our solar ...
A model for the Venus atmosphere involving photochemistry of oxygen, hydrogen, chlorine and sulfur s...
International audienceRecent observations of sulfur oxides (SO2, SO, OCS, and H2SO4) in Venus’ mesos...
Recent observations of sulfur containing species (SO2, SO, OCS, and H2SO4) in Venus’ mesosphere have...
In order to understand the evolution of water on Venus, we must know the hydrogen escape flux as a f...
The depletion of SO2 and H2O in and above the clouds of Venus (45-65 km) cannot be explained by know...
Abstract: The depletion of SO2 and H2O in and above the clouds of Venus (45–65 km) cannot be explain...
The chemical regimes in the atmosphere of Venus vary from photochemistry in the middle atmosphere to...
International audienceSulfur-water chemistry plays an important role in the middle atmosphere of Ven...
International audienceVenus' global-scale cloud and haze layers are composed of complexes of sulfuri...
International audienceVenus' global-scale H2SO4 cloud and haze layers form via the combination of SO...
Venus' atm. is 96.5% CO_2 and 3.5% N_2 with trace abundances of SO_2, OCS, H_2O, HCl, HF, and HBr, a...
The sulphur cycle plays fundamental roles in the chemistry and climate of Venus. Thermodynamic equil...
P.B.R. thanks the Simons Foundation for funding (SCOL awards 599634). P.W. acknowledges funding from...
Sulfur compounds have been observed in the atmospheres of a number of planetary bodies in our solar ...
A model for the Venus atmosphere involving photochemistry of oxygen, hydrogen, chlorine and sulfur s...
International audienceRecent observations of sulfur oxides (SO2, SO, OCS, and H2SO4) in Venus’ mesos...
Recent observations of sulfur containing species (SO2, SO, OCS, and H2SO4) in Venus’ mesosphere have...
In order to understand the evolution of water on Venus, we must know the hydrogen escape flux as a f...
The depletion of SO2 and H2O in and above the clouds of Venus (45-65 km) cannot be explained by know...
Abstract: The depletion of SO2 and H2O in and above the clouds of Venus (45–65 km) cannot be explain...
The chemical regimes in the atmosphere of Venus vary from photochemistry in the middle atmosphere to...
International audienceSulfur-water chemistry plays an important role in the middle atmosphere of Ven...
International audienceVenus' global-scale cloud and haze layers are composed of complexes of sulfuri...
International audienceVenus' global-scale H2SO4 cloud and haze layers form via the combination of SO...
Venus' atm. is 96.5% CO_2 and 3.5% N_2 with trace abundances of SO_2, OCS, H_2O, HCl, HF, and HBr, a...