THOR: a new and flexible global circulation model to explore planetary atmospheres
THOR: a new and flexible global circulation model to explore planetary atmospheres
We have designed and developed, from scratch, a global circulation model (GCM) named THOR that solves the three-dimensional nonhydrostatic Euler equations. Our general approach lifts the commonly used assumptions of a shallow atmosphere and hydrostatic equilibrium. We solve the "pole problem" (where converging meridians on a sphere lead to increasingly smaller time steps near the poles) by implementing an icosahedral grid. Irregularities in the grid, which lead to grid imprinting, are smoothed using the "spring dynamics" technique. We validate our implementation of spring dynamics by examining calculations of the divergence and gradient of test functions. To prevent the computational time step from being bottlenecked by having to resolve sound waves, we implement a split-explicit method together with a horizontally explicit and vertically implicit integration. We validate our GCM by reproducing the Earth and hot-Jupiter-like benchmark tests. THOR was designed to run on graphics processing units (GPUs), which allows for physics modules (radiative transfer, clouds, chemistry) to be added in the future, and is part of the open-source Exoclimes Simulation Platform (www.exoclime.org).
Mendonça, João M.
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Grimm, Simon L.
2e304876-a102-4be9-a7d0-cd58bc71bd5b
Grosheintz, Luc
8e9565c4-ad04-49e4-ac42-4113fea6a255
Heng, Kevin
11e4460d-9575-412c-b350-53e2ef459056
28 September 2016
Mendonça, João M.
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Grimm, Simon L.
2e304876-a102-4be9-a7d0-cd58bc71bd5b
Grosheintz, Luc
8e9565c4-ad04-49e4-ac42-4113fea6a255
Heng, Kevin
11e4460d-9575-412c-b350-53e2ef459056
Mendonça, João M., Grimm, Simon L., Grosheintz, Luc and Heng, Kevin
(2016)
THOR: a new and flexible global circulation model to explore planetary atmospheres.
The Astrophysical Journal, 829 (2), [115].
(doi:10.3847/0004-637X/829/2/115).
Abstract
We have designed and developed, from scratch, a global circulation model (GCM) named THOR that solves the three-dimensional nonhydrostatic Euler equations. Our general approach lifts the commonly used assumptions of a shallow atmosphere and hydrostatic equilibrium. We solve the "pole problem" (where converging meridians on a sphere lead to increasingly smaller time steps near the poles) by implementing an icosahedral grid. Irregularities in the grid, which lead to grid imprinting, are smoothed using the "spring dynamics" technique. We validate our implementation of spring dynamics by examining calculations of the divergence and gradient of test functions. To prevent the computational time step from being bottlenecked by having to resolve sound waves, we implement a split-explicit method together with a horizontally explicit and vertically implicit integration. We validate our GCM by reproducing the Earth and hot-Jupiter-like benchmark tests. THOR was designed to run on graphics processing units (GPUs), which allows for physics modules (radiative transfer, clouds, chemistry) to be added in the future, and is part of the open-source Exoclimes Simulation Platform (www.exoclime.org).
Text
1607.05535v1
- Accepted Manuscript
More information
Accepted/In Press date: 18 July 2016
Published date: 28 September 2016
Identifiers
Local EPrints ID: 496775
URI: http://eprints.soton.ac.uk/id/eprint/496775
ISSN: 0004-637X
PURE UUID: 1a9fc129-faa3-4039-9774-9fc447e3fc0f
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Date deposited: 08 Jan 2025 05:21
Last modified: 10 Jan 2025 03:21
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Contributors
Author:
João M. Mendonça
Author:
Simon L. Grimm
Author:
Luc Grosheintz
Author:
Kevin Heng
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