Atmospheric circulation of hot Jupiters: insensitivity to initial conditions

TL;DR

This study shows that hot Jupiter atmospheric circulation models reach the same steady state regardless of initial conditions, provided certain physical mechanisms are included, reducing uncertainties in modeling their atmospheres.

Contribution

It demonstrates the insensitivity of hot-Jupiter atmospheric models to initial conditions when frictional drag or interior interaction mechanisms are incorporated.

Findings

Models converge to the same steady state regardless of initial jets.

Inclusion of drag or interior interaction allows angular momentum adjustment.

Statistical steady state is unaffected by initial condition variations.

Abstract

The ongoing characterization of hot Jupiters has motivated a variety of circulation models of their atmospheres. Such models must be integrated starting from an assumed initial state, which is typically taken to be a wind-free, rest state. Here, we investigate the sensitivity of hot-Jupiter atmospheric circulation models to initial conditions. We consider two classes of models--shallow-water models, which have proven successful at illuminating the dynamical mechanisms at play on these planets, and full three-dimensional models similar to those being explored in the literature. Models are initialized with zonal jets, and we explore a variety of different initial jet profiles. We demonstrate that, in both classes of models, the final, equilibrated state is independent of initial condition--as long as frictional drag near the bottom of the domain and/or interaction with a specified planetary interior are included so that the atmosphere can adjust angular momentum over time relative to the interior. When such mechanisms are included, otherwise identical models initialized with vastly different initial conditions all converge to the same statistical steady state. In some cases, the models exhibit modest time variability; this variability results in random fluctuations about the statistical steady state, but we emphasize that, even in these cases, the statistical steady state itself does not depend on initial conditions. Although the outcome of hot-Jupiter circulation models depend on details of the radiative forcing and frictional drag, aspects of which remain uncertain, we conclude that the specification of initial conditions is not a source of uncertainty, at least over the parameter range explored in most current models.