Nonequilibrium thermodynamics of circulation regimes in optically-thin, dry atmospheres

TL;DR

This study applies nonequilibrium thermodynamics diagnostics to analyze circulation regimes in optically-thin, dry atmospheres, revealing how rotation rate and surface properties influence efficiency, heat transport, and dissipation.

Contribution

It introduces a novel thermodynamic framework to characterize atmospheric circulation regimes, linking thermodynamic diagnostics with circulation patterns across different planetary parameters.

Findings

Baroclinic circulations exhibit high dissipation and efficiency.

Surface properties mainly influence sensible heat flux dissipation.

High rotation rates lead to zonostrophic, low-dissipation regimes.

Abstract

An extensive analysis of an optically-thin, dry atmosphere at different values of the thermal Rossby number Ro and of the Taylor number Ff is per- formed with a general circulation model by varying the rotation rate {\Omega} and the surface drag {\tau} in a wide parametric range. By using nonequilibrium thermodynamics diagnostics such as material entropy production, efficiency, meridional heat transport and kinetic energy dissipation we characterize in a new way the different circulation regimes. Baroclinic circulations feature high mechanical dissipation, meridional heat transport, material entropy pro- duction and are fairly efficient in converting heat into mechanical work. The thermal dissipation associated with the sensible heat flux is found to depend mainly on the surface properties, almost independent from the rotation rate and very low for quasi-barotropic circulations and regimes approaching equa- torial super-rotation. Slowly rotating, axisymmetric circulations have the highest meridional heat transport. At high rotation rates and intermediate- high drag, atmospheric circulations are zonostrohic with very low mechanical dissipation, meridional heat transport and efficiency. When {\tau} is interpreted as a tunable parameter associated with the turbulent boundary layer trans- fer of momentum and sensible heat, our results confirm the possibility of using the Maximum Entropy Production Principle as a tuning guideline in the range of values of {\Omega}. This study suggests the effectiveness of using fun- damental nonequilibrium thermodynamics for investigating the properties of planetary atmospheres and extends our knowledge of the thermodynamics of the atmospheric circulation regimes.