Mineralogy, structure and habitability of carbon-enriched rocky exoplanets: A laboratory approach

TL;DR

This study uses laboratory experiments to explore the mineralogy and internal structure of carbon-enriched rocky exoplanets, revealing their layered composition and potential observational signatures.

Contribution

It provides the first detailed mineralogical and structural model of carbon-rich exoplanets based on high-pressure experiments and planetary modeling.

Findings

Carbon-enriched exoplanets have a layered structure with a metallic core, silicate mantle, and graphite surface.

Graphite dominates carbon phases at high pressures, with no silicon carbide or carbonates detected.

A 10 wt% graphite layer can significantly reduce the planet's mass and affect its observational properties.

Abstract

Carbon-enriched rocky exoplanets have been proposed around dwarf stars as well as around binary stars, white dwarfs and pulsars. However, the mineralogical make up of such planets is poorly constrained. We performed high-pressure high-temperature laboratory experiments ($P$ = 1$-$2 GPa, $T$ = 1523$-$1823 K) on carbon-enriched chemical mixtures to investigate the deep interiors of Pluto- to Mars-size planets the upper mantles of larger planets. Our results show that these exoplanets, when fully-differentiated, comprise a metallic core, a silicate mantle and a graphite layer on top of the silicate mantle. The silicate mineralogy (olivine, orthopyroxene, clinopyroxene and spinel) is largely unaffected by the amount of carbon. Metals are either two immiscible iron-rich alloys (S-rich and S-poor) or a single iron-rich alloy in the Fe-C-S system with immiscibility depending on the S/Fe ratio and core pressure. Graphite is the dominant carbon-bearing phase at the conditions of our experiments with no traces of silicon carbide or carbonates. If the bulk carbon content is higher than needed to saturate the mantle and the core, graphite would be in the form of an additional layer on top of the silicate mantle assuming differentiation. For a thick enough graphite layer, diamonds would form at the bottom of this layer due to high pressures. We model the interior structure of Kepler-37b and show that a mere 10 wt% graphite layer would decrease its derived mass by 7%, suggesting future space missions that determine both radius and mass of rocky exoplanets with insignificant gaseous envelopes could provide quantitative limits on their carbon content. Future observations of rocky exoplanets with graphite-rich surfaces would show low albedos due to the low reflectance of graphite. The absence of life-bearing elements other than carbon on the surface likely makes them uninhabitable.