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Strong Fractionation of Deuterium and Helium in Sub-Neptune Atmospheres along the Radius Valley

Collin Cherubim, Robin Wordsworth, Renyu Hu, Evgenya L. Shkolnik

2024The Astrophysical Journal18 citationsDOIOpen Access PDF

Abstract

Abstract We simulate atmospheric fractionation in escaping planetary atmospheres using IsoFATE , a new open-source numerical model. We expand the parameter space studied previously to planets with tenuous atmospheres that exhibit the greatest helium and deuterium enhancement. We simulate the effects of extreme-ultraviolet-driven photoevaporation and core-powered mass loss on deuterium–hydrogen and helium–hydrogen fractionation of sub-Neptune atmospheres around G, K, and M stars. Our simulations predict prominent populations of deuterium- and helium-enhanced planets along the upper edge of the radius valley with mean equilibrium temperatures of ≈370 K and as low as 150 K across stellar types. We find that fractionation is mechanism dependent, so constraining He/H and D/H abundances in sub-Neptune atmospheres offers a unique strategy to investigate the origin of the radius valley around low-mass stars. Fractionation is also strongly dependent on retained atmospheric mass, offering a proxy for planetary surface pressure as well as a way to distinguish between desiccated enveloped terrestrials and water worlds. Deuterium-enhanced planets tend to be helium dominated and CH 4 depleted, providing a promising strategy to observe HDO in the 3.7 μ m window. We present a list of promising targets for observational follow-up.

Topics & Concepts

DeuteriumRADIUSHeliumNeptuneAstrobiologyFractionationPhysicsAstrophysicsAstronomyAtomic physicsNuclear physicsChemistryPlanetChromatographyComputer scienceComputer securityAstro and Planetary SciencePlanetary Science and ExplorationIsotope Analysis in Ecology
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