The erosion of large primary atmospheres typically leaves behind substantial secondary atmospheres on temperate rocky planets

Krissansen-Totton, Joshua; Wogan, Nicholas; Thompson, Maggie; Fortney, Jonathan J.

doi:10.1038/s41467-024-52642-6

Nat Commun

2024

DOI: 10.1038/s41467-024-52642-6

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The erosion of large primary atmospheres typically leaves behind substantial secondary atmospheres on temperate rocky planets

Joshua Krissansen-Totton,

Nicholas Wogan,

Maggie Thompson

et al.

Abstract: Exoplanet exploration has revealed that many—perhaps most—terrestrial exoplanets formed with substantial H2-rich envelopes, seemingly in contrast to solar system terrestrials, for which there is scant evidence of long-lived primary atmospheres. It is not known how a long-lived primary atmosphere might affect the subsequent habitability prospects of terrestrial exoplanets. Here, we present a new, self-consistent evolutionary model of the transition from primary to secondary atmospheres. The model incorporates a… Show more

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Convective shutdown in the atmospheres of lava worlds

Nicholls,

Pierrehumbert,

Lichtenberg

et al. 2024

Monthly Notices of the Royal Astronomical Society

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Atmospheric energy transport is central to the cooling of primordial magma oceans. Theoretical studies of atmospheres on lava planets have assumed that convection is the only process involved in setting the atmospheric temperature structure. This significantly influences the ability for a magma ocean to cool. It has been suggested that convective stability in these atmospheres could preclude permanent magma oceans. We develop a new 1D radiative-convective model in order to investigate when the atmospheres overlying magma oceans are convectively stable. Using a coupled interior-atmosphere framework, we simulate the early evolution of two terrestrial-mass exoplanets: TRAPPIST-1 c and HD 63433 d. Our simulations suggest that the atmosphere of HD 63433 d exhibits deep isothermal layers which are convectively stable. However, it is able to maintain a permanent magma ocean and an atmosphere depleted in H2O. It is possible to maintain permanent magma oceans underneath atmospheres without convection. Absorption features of CO2 and SO2 within synthetic emission spectra are associated with mantle redox state, meaning that future observations of HD 63433 d may provide constraints on the geochemical properties of a magma ocean analogous with the early Earth. Simulations of TRAPPIST-1 c indicate that it is expected to have solidified within 100 Myr outgassing a thick atmosphere in the process. Cool isothermal stratospheres generated by low molecular-weight atmospheres can mimic the emission of an atmosphere-less body. Future work should consider how atmospheric escape and chemistry modulates the lifetime of magma oceans, and the role of tidal heating in sustaining atmospheric convection.

show abstract

Convective shutdown in the atmospheres of lava worlds

Nicholls,

Pierrehumbert,

Lichtenberg

et al. 2024

Monthly Notices of the Royal Astronomical Society

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show abstract

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The erosion of large primary atmospheres typically leaves behind substantial secondary atmospheres on temperate rocky planets

Cited by 1 publication

References 111 publications

Convective shutdown in the atmospheres of lava worlds

Convective shutdown in the atmospheres of lava worlds

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