A cool runaway greenhouse without surface magma ocean
Selsis, F.; Leconte, J.; Turbet, M.; Chaverot, G.; Bolmont, E. (2023). A cool runaway greenhouse without surface magma ocean. Nature (Lond.) 620(7973): 287-291. https://dx.doi.org/10.1038/s41586-023-06258-3
In: Nature: International Weekly Journal of Science. Nature Publishing Group: London. ISSN 0028-0836; e-ISSN 1476-4687, meer
Water vapour atmospheres with content equivalent to the Earth’s oceans, resulting from impacts or a high insolation were found to yield a surface magma ocean. This was, however, a consequence of assuming a fully convective structure. Here, we report using a consistent climate model that pure steam atmospheres are commonly shaped by radiative layers, making their thermal structure strongly dependent on the stellar spectrum and internal heat flow. The surface is cooler when an adiabatic profile is not imposed; melting Earth’s crust requires an insolation several times higher than today, which will not happen during the main sequence of the Sun. Venus’s surface can solidify before the steam atmosphere escapes, which is the opposite of previous works. Around the reddest stars (Teff < 3,000 K), surface magma oceans cannot form by stellar forcing alone, whatever the water content. These findings affect observable signatures of steam atmospheres and exoplanet mass–radius relationships, drastically changing current constraints on the water content of TRAPPIST-1 planets. Unlike adiabatic structures, radiative–convective profiles are sensitive to opacities. New measurements of poorly constrained high-pressure opacities, in particular far from the H2O absorption bands, are thus necessary to refine models of steam atmospheres, which are important stages in terrestrial planet evolution.
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