A quantitative scaling theory for meridional heat transport in planetary atmospheres and oceans

TL;DR

This paper develops a quantitative scaling theory for meridional heat transport in planetary atmospheres and oceans, accounting for planetary curvature effects on turbulent flows and temperature profiles.

Contribution

It extends existing vortex-based heat transport models to include planetary curvature, providing a parameterization for temperature profiles and instability levels.

Findings

Quantitative prediction of meridional temperature profiles.

Inclusion of planetary curvature effects in heat transport modeling.

Estimation of the criticality of planetary atmospheric and oceanic flows.

Abstract

The meridional temperature profile of the upper layers of planetary atmospheres is set through a balance between differential radiative heating by a nearby star, or by intrinsic heat fluxes emanating from the deep interior, and the redistribution of that heat across latitudes by turbulent flows. These flows spontaneously arise through baroclinic instability of the meridional temperature gradients maintained by the forcing. When planetary curvature is neglected, this turbulence takes the form of coherent vortices that mix the meridional temperature profiles. However, the curvature of the planet favors the emergence of Rossby waves and zonal jets that restrict the meridional wandering of the fluid columns, thereby reducing the mixing efficiency across latitudes. A similar situation arises in the ocean, where the baroclinic instability of zonal currents leads to enhanced meridional heat transport by a turbulent flow consisting of vortices and zonal jets. A recent scaling theory for the turbulent heat transport by vortices is extended to include the impact of planetary curvature, in the framework of the two-layer quasigeostrophic beta-plane model. This leads to a quantitative parameterization providing the meridional temperature profile in terms of the externally imposed heat flux in an idealized model of planetary atmospheres and oceans. In addition, it provides a quantitative prediction for the emergent criticality, i.e., the degree of instability in a canonical model of planetary atmosphere or ocean.