利用 MPAS-A 模拟 TRAPPIST-1e 的气候并与其他 GCMs 进行比较

IF 3.8 Q2 ASTRONOMY & ASTROPHYSICS The Planetary Science Journal Pub Date : 2024-07-08 DOI:10.3847/psj/ad5546
Lixiang Gu, Jun Yang, Mingyu Yan
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引用次数: 0

摘要

日侧对流是造成潮汐锁定行星气候的最重要因素之一。考虑到模拟对流这一长期存在的难题,我们采用了一个名为 "跨尺度大气预测模型 "的对流解析模型,并进行了一系列空间分辨率从960到10千米的模拟。我们以TRAPPIST-1e(一颗潜在的宜居系外行星)为目标,旨在与TRAPPIST-1宜居大气层相互比较项目的结果进行比较分析。在整体气候状态方面,我们的模拟结果再次证实了之前的大气环流模型(GCM)的结论。广泛的亚恒星云团和错综复杂的云街特征都得到了成功再现。在我们的分辨率范围内,不同网格分辨率的影响微乎其微,尽管在夜间观测到的灵敏度略有提高。在网格分辨率评估和 GCM 相互比较方案中,主要差异集中在与云有关的变量上,包括云相(液态和冰态)、数量和高度。此外,我们还探讨了对相位曲线和过境光谱的影响。
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Simulated Climate of TRAPPIST-1e Using MPAS-A and Comparisons with Other GCMs
Dayside convection is one of the most important contributors to a tidally locked planet’s climate. Considering the long-standing challenge of simulating convections, we employ a convection-resolving model known as the Model for Prediction across Scales—Atmosphere and perform a series of simulations with spatial resolution ranging from 960 to 10 km. With TRAPPIST-1e, a potentially habitable exoplanet, as the target, we aim to draw a comparative analysis against the results from the TRAPPIST-1 Habitable Atmosphere Intercomparison project. Regarding the overall climate states, our simulations reaffirm the findings of the previous general circulation model (GCM). Both the extensive substellar cloud cluster and the intricate cloud street feature are successfully reproduced. The influence of varying grid resolution exhibits a remarkably marginal impact across our resolution spectrum, albeit with a slightly heightened sensitivity observed at the nightside. Major differences center around the cloud-related variables, including cloud phase (liquid and ice), amount, and height, in both the grid resolution assessments and GCM intercomparison scenarios. Furthermore, we explore the repercussions on the phase curve and transit spectrum.
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来源期刊
The Planetary Science Journal
The Planetary Science Journal Earth and Planetary Sciences-Geophysics
CiteScore
5.20
自引率
0.00%
发文量
249
审稿时长
15 weeks
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