Abstract
The climate and circulation of a terrestrial planet are governed by, among other things, the distance to its host star, its size, rotation rate, obliquity, atmospheric composition and gravity. Here we explore the effects of the last of these, the Newtonian gravitational acceleration, on its atmosphere and climate. We first demonstrate that, if the atmosphere obeys the hydrostatic primitive equations, which are a very good approximation for most terrestrial atmospheres, and if the radiative forcing is unaltered, changes in gravity have no effect at all on the circulation except for a vertical rescaling. That is to say, the effects of gravity may be completely scaled away and the circulation is unaltered. However, if the atmosphere contains a dilute condensible that is radiatively active, such as water or methane, then an increase in gravity will generally lead to a cooling of the planet because the total path length of the condensible will be reduced as gravity increases, leading to a reduction in the greenhouse effect. Furthermore, the specific humidity will decrease, leading to changes in the moist adiabatic lapse rate, in the Equator‐to‐Pole heat transport, and in the surface energy balance because of changes in the sensible and latent fluxes. These effects are all demonstrated both by theoretical arguments and by numerical simulations with moist and dry general circulation models.
Highlights
The climate of a terrestrial planet depends on an almost uncountable number of factors, including the distance to its host star, the nature of that host star, the size and rotation rate of the planet, the atmospheric composition and many other factors
For example, Read (2011) and Wang et al (2018) describe how various nondimensional parameters describe the general circulation of a large class of planetary atmospheres, Kaspi and Showman (2015) illustrate how the planetary circulation patterns vary over a wide range of orbital parameters, and Pierrehumbert (2010) applies building blocks based on elementary physical principles to construct a plentiful panoply of planetary climates
We explore the effects of these changes using some idealized numerical simulations: first, in Section 4, we describe the radiative effects of those changes, and in Sections 5–7 we explore the dynamical effects of the changes in specific humidity, In section 8 we look at the role of gravity with a more complete model, and section 9 we provide our conclusions
Summary
TITLE The effects of gravity on the climate and circulation of a terrestrial planet AUTHORS Thomson, SI; Vallis, GK JOURNAL Quarterly Journal of the Royal Meteorological Society DEPOSITED IN ORE 04 September 2019. COPYRIGHT AND REUSE Open Research Exeter makes this work available in accordance with publisher policies. A NOTE ON VERSIONS The version presented here may differ from the published version. You are advised to consult the published version for pagination, volume/issue and date of publication arXiv:1901.11426v1 [astro-ph.EP] 31 Jan 2019
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