Interior Structures and Tidal Heating in the TRAPPIST-1 Planets

TL;DR

This study models the interior structures and tidal heating of the TRAPPIST-1 planets, revealing potential magma oceans, habitability prospects, and the importance of interior composition and heat transport for understanding their geodynamics.

Contribution

It provides the first detailed interior and tidal heating models for all seven TRAPPIST-1 planets, highlighting their potential for habitable conditions and volcanic activity.

Findings

Planets b and c may have magma oceans due to tidal heating.

Planets d and e are most likely to be habitable.

Tidal heat fluxes are significantly higher than Earth's.

Abstract

With seven planets, the TRAPPIST-1 system has the largest number of exoplanets discovered in a single system so far. The system is of astrobiological interest, because three of its planets orbit in the habitable zone of the ultracool M dwarf. Assuming the planets are composed of non-compressible iron, rock, and H$_2$O, we determine possible interior structures for each planet. To determine how much tidal heat may be dissipated within each planet, we construct a tidal heat generation model using a single uniform viscosity and rigidity for each planet based on the planet's composition. With the exception of TRAPPIST-1c, all seven of the planets have densities low enough to indicate the presence of significant H$_2$O in some form. Planets b and c experience enough heating from planetary tides to maintain magma oceans in their rock mantles; planet c may have eruptions of silicate magma on its surface, which may be detectable with next-generation instrumentation. Tidal heat fluxes on planets d, e, and f are lower, but are still twenty times higher than Earth's mean heat flow. Planets d and e are the most likely to be habitable. Planet d avoids the runaway greenhouse state if its albedo is $\gtrsim$ 0.3. Determining the planet's masses within $\sim0.1$ to 0.5 Earth masses would confirm or rule out the presence of H$_2$O and/or iron in each planet, and permit detailed models of heat production and transport in each planet. Understanding the geodynamics of ice-rich planets f, g, and h requires more sophisticated modeling that can self-consistently balance heat production and transport in both rock and ice layers.