THOR 2.0: major improvements to the open-source general circulation model
THOR 2.0: major improvements to the open-source general circulation model
THOR is the first open-source general circulation model (GCM) developed from scratch to study the atmospheres and climates of exoplanets, free from Earth- or solar-system-centric tunings. It solves the general nonhydrostatic Euler equations (instead of the primitive equations) on a sphere using the icosahedral grid. In the current study, we report major upgrades to THOR, building on the work of Mendonça et al. First, while the horizontally explicit and vertically implicit integration scheme is the same as that described in Mendonça et al., we provide a clearer description of the scheme and improve its implementation in the code. The differences in implementation between the hydrostatic shallow, quasi-hydrostatic deep, and nonhydrostatic deep treatments are fully detailed. Second, standard physics modules are added: two-stream, double-gray radiative transfer and dry convective adjustment. Third, THOR is tested on additional benchmarks: tidally locked Earth, deep hot Jupiter, acoustic wave, and gravity wave. Fourth, we report that differences between the hydrostatic and nonhydrostatic simulations are negligible in the Earth case but pronounced in the hot Jupiter case. Finally, the effects of the so-called "sponge layer," a form of drag implemented in most GCMs to provide numerical stability, are examined. Overall, these upgrades have improved the flexibility, user-friendliness, and stability of THOR.248
Deitrick, Russell
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Mendonça, João M.
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Schroffenegger, Urs
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Grimm, Simon L.
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Tsai, Shang-Min
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Heng, Kevin
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10 June 2020
Deitrick, Russell
7e0f9786-935b-4c3b-8a57-1e8b7b85b075
Mendonça, João M.
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Schroffenegger, Urs
afe4224c-50d6-4f01-9f69-5b2bdcc269fb
Grimm, Simon L.
2e304876-a102-4be9-a7d0-cd58bc71bd5b
Tsai, Shang-Min
fd5f43d2-042b-44a2-bf50-c556b74ad84e
Heng, Kevin
11e4460d-9575-412c-b350-53e2ef459056
Deitrick, Russell, Mendonça, João M., Schroffenegger, Urs, Grimm, Simon L., Tsai, Shang-Min and Heng, Kevin
(2020)
THOR 2.0: major improvements to the open-source general circulation model.
The Astrophysical Journal Supplement Series, 248 (30).
(doi:10.3847/1538-4365/ab930e).
Abstract
THOR is the first open-source general circulation model (GCM) developed from scratch to study the atmospheres and climates of exoplanets, free from Earth- or solar-system-centric tunings. It solves the general nonhydrostatic Euler equations (instead of the primitive equations) on a sphere using the icosahedral grid. In the current study, we report major upgrades to THOR, building on the work of Mendonça et al. First, while the horizontally explicit and vertically implicit integration scheme is the same as that described in Mendonça et al., we provide a clearer description of the scheme and improve its implementation in the code. The differences in implementation between the hydrostatic shallow, quasi-hydrostatic deep, and nonhydrostatic deep treatments are fully detailed. Second, standard physics modules are added: two-stream, double-gray radiative transfer and dry convective adjustment. Third, THOR is tested on additional benchmarks: tidally locked Earth, deep hot Jupiter, acoustic wave, and gravity wave. Fourth, we report that differences between the hydrostatic and nonhydrostatic simulations are negligible in the Earth case but pronounced in the hot Jupiter case. Finally, the effects of the so-called "sponge layer," a form of drag implemented in most GCMs to provide numerical stability, are examined. Overall, these upgrades have improved the flexibility, user-friendliness, and stability of THOR.248
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Deitrick_2020_ApJS_248_30
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Accepted/In Press date: 12 May 2020
Published date: 10 June 2020
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Local EPrints ID: 496766
URI: http://eprints.soton.ac.uk/id/eprint/496766
ISSN: 0067-0049
PURE UUID: 4d1c94cc-9ab4-43db-91d2-edacafd9baad
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Date deposited: 08 Jan 2025 05:21
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Russell Deitrick
Author:
João M. Mendonça
Author:
Urs Schroffenegger
Author:
Simon L. Grimm
Author:
Shang-Min Tsai
Author:
Kevin Heng
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