Steamworlds: atmospheric structure and critical mass of planets accreting icy pebbles

TL;DR

This paper models the atmospheric structure of icy pebble-accreting planetary cores, identifying critical core masses for gas accretion and how they depend on various physical parameters.

Contribution

It introduces a detailed atmospheric model for icy pebble accretion, revealing complex dependencies of critical mass on pebble properties and opacity, advancing core accretion theory.

Findings

Critical core mass for gas accretion is 1-3 Earth masses.

Atmospheric structure varies with core mass, temperature, and water phase.

Multiple core-mass maxima can occur depending on parameters.

Abstract

In the core accretion model, gas-giant planets first form a solid core, which then accretes gas from a protoplanetary disk when the core exceeds a critical mass. Here, we model the atmosphere of a core that grows by accreting ice-rich pebbles. The ice fraction of pebbles evaporates in warm regions of the atmosphere, saturating it with water vapor. Excess water precipitates to lower altitudes. Beneath an outer radiative region, the atmosphere is convective, following a moist adiabat in saturated regions due to water condensation and precipitation. Atmospheric mass, density and temperature increase with core mass. For nominal model parameters, planets with core masses (ice + rock) between 0.08 and 0.16 Earth masses have surface temperatures between 273 K and 647 K and form an ocean. In more massive planets, water exists as a super-critical convecting fluid mixed with gas from the disk. Typically, the core mass reaches a maximum (the critical mass) as a function of the total mass when the core is 2-5 Earth masses. The critical mass depends in a complicated way on pebble size, mass flux, and dust opacity due to the occasional appearance of multiple core-mass maxima. The core mass for an atmosphere of 50 percent hydrogen and helium may be a more robust indicator of the onset of gas accretion. This mass is typically 1-3 Earth masses for pebbles that are 50 percent ice by mass, increasing with opacity and pebble flux, and decreasing with pebble ice/rock ratio.