Three‐dimensional Venus cloud structure simulated by a general circulation model
Three‐dimensional Venus cloud structure simulated by a general circulation model
The clouds have a great impact on Venus's energy budget and climate evolution, but its three-dimensional structure is still not well understood. Here we incorporate a simple Venus cloud physics scheme into a flexible GCM to investigate the three-dimensional cloud spatial variability. Our simulations show good agreement with observations in terms of the vertical profiles of clouds and H 2SO 4 vapor. H 2O vapor is overestimated above the clouds due to efficient transport in the cloud region. The cloud top decreases as latitude increases, qualitatively consistent with Venus Express observations. The underlying mechanism is the combination of H 2SO 4 chemical production and meridional circulation. The mixing ratios of H 2SO 4 at 50–60 km and H 2O vapors in the main cloud deck basically exhibit maxima around the equator, due to the effect of temperature's control on the saturation vapor mixing ratios of the two species. The cloud mass distribution is subject to both H 2SO 4 chemical production and dynamical transport and shows a pattern that peaks around the equator in the upper cloud while peaks at mid-high latitudes in the middle cloud. At low latitudes, H 2SO 4 and H 2O vapors, cloud mass loading and acidity show semidiurnal variations at different altitude ranges, which can be validated against future missions. Our model emphasizes the complexity of the Venus climate system and the great need for more observations and simulations to unravel its spatial variability and underlying atmospheric and/or geological processes.
Venus, atmospheric dynamics, cloud physics, general-circulation model
Shao, Wencheng D.
873d3e33-560b-4d60-8e3d-0c7c74990ee8
Mendonça, João M.
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Dai, Longkang
0602a42d-23c2-4d50-80ed-eb14dd83a0d6
Shao, Wencheng D.
873d3e33-560b-4d60-8e3d-0c7c74990ee8
Mendonça, João M.
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Dai, Longkang
0602a42d-23c2-4d50-80ed-eb14dd83a0d6
Shao, Wencheng D., Mendonça, João M. and Dai, Longkang
(2024)
Three‐dimensional Venus cloud structure simulated by a general circulation model.
Journal of Geophysical Research: Planets, 129 (7), [e2023JE008088].
(doi:10.1029/2023JE008088).
Abstract
The clouds have a great impact on Venus's energy budget and climate evolution, but its three-dimensional structure is still not well understood. Here we incorporate a simple Venus cloud physics scheme into a flexible GCM to investigate the three-dimensional cloud spatial variability. Our simulations show good agreement with observations in terms of the vertical profiles of clouds and H 2SO 4 vapor. H 2O vapor is overestimated above the clouds due to efficient transport in the cloud region. The cloud top decreases as latitude increases, qualitatively consistent with Venus Express observations. The underlying mechanism is the combination of H 2SO 4 chemical production and meridional circulation. The mixing ratios of H 2SO 4 at 50–60 km and H 2O vapors in the main cloud deck basically exhibit maxima around the equator, due to the effect of temperature's control on the saturation vapor mixing ratios of the two species. The cloud mass distribution is subject to both H 2SO 4 chemical production and dynamical transport and shows a pattern that peaks around the equator in the upper cloud while peaks at mid-high latitudes in the middle cloud. At low latitudes, H 2SO 4 and H 2O vapors, cloud mass loading and acidity show semidiurnal variations at different altitude ranges, which can be validated against future missions. Our model emphasizes the complexity of the Venus climate system and the great need for more observations and simulations to unravel its spatial variability and underlying atmospheric and/or geological processes.
Text
JGR Planets - 2024 - Shao - Three‐Dimensional Venus Cloud Structure Simulated by a General Circulation Model
- Version of Record
More information
Accepted/In Press date: 15 July 2024
e-pub ahead of print date: 24 July 2024
Keywords:
Venus, atmospheric dynamics, cloud physics, general-circulation model
Identifiers
Local EPrints ID: 497544
URI: http://eprints.soton.ac.uk/id/eprint/497544
ISSN: 2169-9100
PURE UUID: f27de029-1b0f-4a07-8c2f-ab5c5fbecc3c
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Date deposited: 27 Jan 2025 17:50
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Wencheng D. Shao
Author:
João M. Mendonça
Author:
Longkang Dai
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