Water Evolution & Inventories of Super-Earths Orbiting Late M Dwarfs

TL;DR

This study models water cycling and loss on super-Earths orbiting late M-dwarfs, revealing how initial water content and planetary mass influence surface conditions and habitability over billions of years.

Contribution

It introduces a comprehensive simulation of water evolution on super-Earths, highlighting the impact of planetary mass and initial water inventory on surface habitability.

Findings

Water loss decreases with planetary mass.

Larger planets sequester more water in the mantle.

Most planets do not become Dune-like dry worlds.

Abstract

Super-Earths orbiting M-dwarf stars may be the most common habitable planets in the Universe. However, their habitability is threatened by intense irradiation from their host stars, which drives the escape of water to space and can lead to surface desiccation. We present simulation results of a box model of water cycling between interior and atmosphere and loss to space, for terrestrial planets of mass 1--8 $M_\oplus$ orbiting in the habitable zone of a late M-dwarf. Energy-limited loss decreases with planetary mass, while diffusion-limited loss increases with mass. Depending on where it orbits in the habitable zone, a 1 $M_\oplus$ planet that starts with 3--8 Earth Oceans can end up with an Earth-like surface of oceans and exposed continents; for an 8 $M_\oplus$ super-Earth, that range is 3--12 Earth Oceans. Planets initialized with more water end up as waterworlds with no exposed continents, while planets that start with less water have desiccated surfaces by 5 Gyr. Since the mantles of terrestrial planets can hold much more water than is currently present in Earth's atmosphere, none of our simulations result in Dune planets -- such planets may be less common than previously thought. Further, more water becomes sequestered within the mantle for larger planets. A super-Earth at the inner edge of the habitable zone tends to end up as either a waterworld or with a desiccated surface; only a narrow range of initial water inventory yields an Earth-like surface.