Climates of Warm Earth-like Planets I: 3-D Model Simulations.

IF 8.6 1区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS
Astrophysical Journal Supplement Series Pub Date : 2018-12-01 Epub Date: 2018-12-05 DOI:10.3847/1538-4365/aae9e1
M J Way, Anthony D Del Genio, Igor Aleinov, Thomas L Clune, Maxwell Kelley, Nancy Y Kiang
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引用次数: 54

Abstract

We present a large ensemble of simulations of an Earth-like world with increasing insolation and rotation rate. Unlike previous work utilizing idealized aquaplanet configurations we focus our simulations on modern Earth-like topography. The orbital period is the same as modern Earth, but with zero obliquity and eccentricity. The atmosphere is 1 bar N2-dominated with CO2=400 ppmv and CH4=1 ppmv. The simulations include two types of oceans; one without ocean heat transport (OHT) between grid cells as has been commonly used in the exoplanet literature, while the other is a fully coupled dynamic bathtub type ocean. The dynamical regime transitions that occur as day length increases induce climate feedbacks producing cooler temperatures, first via the reduction of water vapor with increasing rotation period despite decreasing shortwave cooling by clouds, and then via decreasing water vapor and increasing shortwave cloud cooling, except at the highest insolations. Simulations without OHT are more sensitive to insolation changes for fast rotations while slower rotations are relatively insensitive to ocean choice. OHT runs with faster rotations tend to be similar with gyres transporting heat poleward making them warmer than those without OHT. For slower rotations OHT is directed equator-ward and no high latitude gyres are apparent. Uncertainties in cloud parameterization preclude a precise determination of habitability but do not affect robust aspects of exoplanet climate sensitivity. This is the first paper in a series that will investigate aspects of habitability in the simulations presented herein. The datasets from this study are opensource and publicly available.

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暖地类行星的气候I:三维模型模拟。
我们展示了一个类似地球的世界,其日射和自转速度都在增加。与之前使用理想的水行星配置的工作不同,我们将模拟重点放在现代类地地形上。轨道周期与现代地球相同,但倾角和离心率为零。大气为1巴N2,CO2=400 ppmv,CH4=1 ppmv。模拟包括两种类型的海洋;一个没有系外行星文献中常用的网格单元之间的海洋热传输(OHT),而另一个是完全耦合的动态浴缸型海洋。随着日照时间的增加,发生的动力状态转换会引发气候反馈,产生较冷的温度,首先是通过水蒸气的减少和自转周期的增加,尽管云层的短波冷却减少,然后是通过水蒸汽的减少和短波云冷却的增加,除非在最高日照量。没有OHT的模拟对快速旋转的日照变化更敏感,而慢速旋转对海洋选择相对不敏感。旋转速度更快的OHT运行往往与向极地输送热量的环流相似,使其比没有OHT的环流更温暖。对于较慢的自转,OHT指向赤道,没有明显的高纬度环流。云参数化的不确定性阻碍了对宜居性的精确确定,但不会影响系外行星气候敏感性的稳健方面。这是一系列论文中的第一篇,将在本文的模拟中研究可居住性的各个方面。这项研究的数据集是开源的,可以公开获得。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Astrophysical Journal Supplement Series
Astrophysical Journal Supplement Series 地学天文-天文与天体物理
CiteScore
14.50
自引率
5.70%
发文量
264
审稿时长
2 months
期刊介绍: The Astrophysical Journal Supplement (ApJS) serves as an open-access journal that publishes significant articles featuring extensive data or calculations in the field of astrophysics. It also facilitates Special Issues, presenting thematically related papers simultaneously in a single volume.
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