Toward consistent modeling of atmospheric chemistry and dynamics in exoplanets: validation and generalization of the chemical relaxation method
Toward consistent modeling of atmospheric chemistry and dynamics in exoplanets: validation and generalization of the chemical relaxation method
Motivated by the work of Cooper & Showman, we revisit the chemical relaxation method, which seeks to enhance the computational efficiency of chemical kinetics calculations by replacing the chemical network with a handful of independent source/sink terms. Chemical relaxation solves the evolution of the system and can treat disequilibrium chemistry, as the source/sink terms are driven toward chemical equilibrium on a prescribed chemical timescale, but it has surprisingly never been validated. First, we generalize the treatment by forgoing the use of a single chemical timescale, instead developing a pathway analysis tool that allows us to identify the rate-limiting reaction as a function of temperature and pressure. For the interconversion between methane and carbon monoxide, and between ammonia and molecular nitrogen, we identify the key rate-limiting reactions for conditions relevant to currently characterizable exo-atmospheres (500–3000 K, 0.1 mbar to 1 kbar). Second, we extend chemical relaxation to include carbon dioxide and water. Third, we examine the role of metallicity and the carbon-to-oxygen ratio in chemical relaxation. Fourth, we apply our pathway analysis tool to diagnose the differences between our chemical network and that of Moses and Venot. Finally, we validate the chemical relaxation method against full chemical kinetics calculations in one dimension. For WASP-18b-, HD 189733b-, and GJ 1214-b-like atmospheres, we show that chemical relaxation is mostly accurate to within an order of magnitude, a factor of 2, and ∼10%, respectively. The level of accuracy attained allows for the chemical relaxation method to be included in three-dimensional general circulation models.
Tsai, Shang-Min
fd5f43d2-042b-44a2-bf50-c556b74ad84e
Kitzmann, Daniel
af1659b8-c27f-4d1b-b7a2-afaeb944af07
Lyons, James R.
fe6a17d1-ee52-4fcb-9085-e80c4e83a5bf
Mendonça, João
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Grimm, Simon L.
2e304876-a102-4be9-a7d0-cd58bc71bd5b
Heng, Kevin
11e4460d-9575-412c-b350-53e2ef459056
19 July 2018
Tsai, Shang-Min
fd5f43d2-042b-44a2-bf50-c556b74ad84e
Kitzmann, Daniel
af1659b8-c27f-4d1b-b7a2-afaeb944af07
Lyons, James R.
fe6a17d1-ee52-4fcb-9085-e80c4e83a5bf
Mendonça, João
cb29fe08-eb94-4fad-8eba-eac1c5de491b
Grimm, Simon L.
2e304876-a102-4be9-a7d0-cd58bc71bd5b
Heng, Kevin
11e4460d-9575-412c-b350-53e2ef459056
Tsai, Shang-Min, Kitzmann, Daniel, Lyons, James R., Mendonça, João, Grimm, Simon L. and Heng, Kevin
(2018)
Toward consistent modeling of atmospheric chemistry and dynamics in exoplanets: validation and generalization of the chemical relaxation method.
The Astrophysical Journal, 862 (1), [31].
(doi:10.3847/1538-4357/aac834).
Abstract
Motivated by the work of Cooper & Showman, we revisit the chemical relaxation method, which seeks to enhance the computational efficiency of chemical kinetics calculations by replacing the chemical network with a handful of independent source/sink terms. Chemical relaxation solves the evolution of the system and can treat disequilibrium chemistry, as the source/sink terms are driven toward chemical equilibrium on a prescribed chemical timescale, but it has surprisingly never been validated. First, we generalize the treatment by forgoing the use of a single chemical timescale, instead developing a pathway analysis tool that allows us to identify the rate-limiting reaction as a function of temperature and pressure. For the interconversion between methane and carbon monoxide, and between ammonia and molecular nitrogen, we identify the key rate-limiting reactions for conditions relevant to currently characterizable exo-atmospheres (500–3000 K, 0.1 mbar to 1 kbar). Second, we extend chemical relaxation to include carbon dioxide and water. Third, we examine the role of metallicity and the carbon-to-oxygen ratio in chemical relaxation. Fourth, we apply our pathway analysis tool to diagnose the differences between our chemical network and that of Moses and Venot. Finally, we validate the chemical relaxation method against full chemical kinetics calculations in one dimension. For WASP-18b-, HD 189733b-, and GJ 1214-b-like atmospheres, we show that chemical relaxation is mostly accurate to within an order of magnitude, a factor of 2, and ∼10%, respectively. The level of accuracy attained allows for the chemical relaxation method to be included in three-dimensional general circulation models.
Text
1711.08492v2
- Accepted Manuscript
More information
Accepted/In Press date: 25 May 2018
Published date: 19 July 2018
Identifiers
Local EPrints ID: 496769
URI: http://eprints.soton.ac.uk/id/eprint/496769
ISSN: 0004-637X
PURE UUID: cda6afe1-43cc-48df-9733-184d1f47d186
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Date deposited: 08 Jan 2025 05:21
Last modified: 10 Jan 2025 03:21
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Contributors
Author:
Shang-Min Tsai
Author:
Daniel Kitzmann
Author:
James R. Lyons
Author:
João Mendonça
Author:
Simon L. Grimm
Author:
Kevin Heng
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