Uranus evolution models with simple thermal boundary layers

TL;DR

This paper presents new Uranus evolution models that incorporate a simple thermal boundary layer to explain its low luminosity, aligning with observed gravity data and suggesting a stratified interior with rocks and a possible equilibrium state.

Contribution

Introduction of a thermal boundary layer in Uranus models to reconcile low luminosity with gravity data, advancing understanding of Ice Giant interior structure and evolution.

Findings

Thermal boundary layer explains low luminosity of Uranus.

Models suggest a stratified interior with rocks and a possible equilibrium state.

Deep interior can be warmer than adiabatic models due to the thermal boundary.

Abstract

The strikingly low luminosity of Uranus (Teff ~ Teq) constitutes a long-standing challenge to our understanding of Ice Giant planets. Here we present the first Uranus structure and evolution models that are constructed to agree with both the observed low luminosity and the gravity field data. Our models make use of modern ab initio equations of state at high pressures for the icy components water, methane, and ammonia. Proceeding step by step, we confirm that adiabatic models yield cooling times that are too long, even when uncertainties in the ice:rock ratio (I:R) are taken into account. We then argue that the transition between the ice/rock-rich interior and the H/He-rich outer envelope should be stably stratified. Therefore, we introduce a simple thermal boundary and adjust it to reproduce the low luminosity. Due to this thermal boundary, the deep interior of the Uranus models are up to 2--3 warmer than adiabatic models, necessitating the presence of rocks in the deep interior with a possible I:R of $1\times$ solar. Finally, we allow for an equilibrium evolution (Teff ~ Teq) that begun prior to the present day, which would therefore no longer require the current era to be a "special time" in Uranus' evolution. In this scenario, the thermal boundary leads to more rapid cooling of the outer envelope. When Teff ~ Teq is reached, a shallow, subadiabatic zone in the atmosphere begins to develop. Its depth is adjusted to meet the luminosity constraint. This work provides a simple foundation for future Ice Giant structure and evolution models, that can be improved by properly treating the heat and particle fluxes in the diffusive zones.