General circulation model errors are variable across exoclimate parameter spaces
General circulation model errors are variable across exoclimate parameter spaces
General circulation models (GCMs) are often used to explore exoclimate parameter spaces and classify atmospheric circulation regimes. Models are tuned to give reasonable climate states for standard test cases, such as the Held–Suarez test, and then used to simulate diverse exoclimates by varying input parameters such as rotation rates, instellation, atmospheric optical properties, frictional timescales, and so on. In such studies, there is an implicit assumption that the model works reasonably well for the standard test case will be credible at all points in an arbitrarily wide parameter space. Here, we test this assumption using the open-source GCM THOR to simulate atmospheric circulation on tidally locked Earth-like planets with rotation periods of 0.1–100 days. We find that the model error, as quantified by the ratio between physical and spurious numerical contributions to the angular momentum balance, is extremely variable across this range of rotation periods with some cases where numerical errors are the dominant component. Increasing model grid resolution does improve errors, but using a higher-order numerical diffusion scheme can sometimes magnify errors for finite-volume dynamical solvers. We further show that to minimize error and make the angular momentum balance more physical within our model, the surface friction timescale must be smaller than the rotational timescale.
Kopparla, Pushkar
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Deitrick, Russell
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Heng, Kevin
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Mendonça, João M.
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Hammond, Mark
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9 December 2021
Kopparla, Pushkar
6b3202bd-25af-44af-90c0-e2897d9bfbaa
Deitrick, Russell
7e0f9786-935b-4c3b-8a57-1e8b7b85b075
Heng, Kevin
11e4460d-9575-412c-b350-53e2ef459056
Mendonça, João M.
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Hammond, Mark
9555fec5-3324-4f5c-bc96-863ff17f7242
Kopparla, Pushkar, Deitrick, Russell, Heng, Kevin, Mendonça, João M. and Hammond, Mark
(2021)
General circulation model errors are variable across exoclimate parameter spaces.
The Astrophysical Journal, 923 (1), [39].
(doi:10.3847/1538-4357/ac2d27).
Abstract
General circulation models (GCMs) are often used to explore exoclimate parameter spaces and classify atmospheric circulation regimes. Models are tuned to give reasonable climate states for standard test cases, such as the Held–Suarez test, and then used to simulate diverse exoclimates by varying input parameters such as rotation rates, instellation, atmospheric optical properties, frictional timescales, and so on. In such studies, there is an implicit assumption that the model works reasonably well for the standard test case will be credible at all points in an arbitrarily wide parameter space. Here, we test this assumption using the open-source GCM THOR to simulate atmospheric circulation on tidally locked Earth-like planets with rotation periods of 0.1–100 days. We find that the model error, as quantified by the ratio between physical and spurious numerical contributions to the angular momentum balance, is extremely variable across this range of rotation periods with some cases where numerical errors are the dominant component. Increasing model grid resolution does improve errors, but using a higher-order numerical diffusion scheme can sometimes magnify errors for finite-volume dynamical solvers. We further show that to minimize error and make the angular momentum balance more physical within our model, the surface friction timescale must be smaller than the rotational timescale.
Text
2110.10925v1
- Accepted Manuscript
More information
Accepted/In Press date: 4 October 2021
Published date: 9 December 2021
Identifiers
Local EPrints ID: 497446
URI: http://eprints.soton.ac.uk/id/eprint/497446
ISSN: 0004-637X
PURE UUID: db43b2d5-319d-4088-b08b-5fca7970c16f
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Date deposited: 23 Jan 2025 17:30
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Pushkar Kopparla
Author:
Russell Deitrick
Author:
Kevin Heng
Author:
João M. Mendonça
Author:
Mark Hammond
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