The climate system and the second law of thermodynamics

TL;DR

This paper reviews how the second law of thermodynamics constrains Earth's climate, emphasizing entropy production from radiative and moist processes, and discusses implications for climate modeling and change.

Contribution

It derives an entropy budget for the climate system incorporating the hydrological cycle and explores thermodynamic principles applied to climate phenomena.

Findings

Entropy production is crucial for understanding atmospheric circulations.

Water vapor increases significantly with climate change, affecting entropy.

Variational and statistical mechanics approaches offer insights into climate dynamics.

Abstract

The second law of thermodynamics implies a relationship between the net entropy export by the Earth and its internal irreversible entropy production. The application of this constraint for the purpose of understanding Earth's climate is reviewed. Both radiative processes and material processes are responsible for irreversible entropy production in the climate system. Focusing on material processes, an entropy budget for the climate system is derived which accounts for the multi-phase nature of the hydrological cycle. The entropy budget facilitates a heat-engine perspective of atmospheric circulations that has been used to propose theories for convective updraft velocities, tropical cyclone intensity, and the atmospheric meridional heat transport. Such theories can only be successful, however, if they properly account for the irreversible entropy production associated with water in all its phases in the atmosphere. Irreversibility associated with such moist processes is particularly important in the context of global climate change, for which the concentration of water vapor in the atmosphere is expected to increase, and recent developments toward understanding the response of the atmospheric heat engine to climate change are discussed. Finally, the application of variational approaches to the climate and geophysical flows is briefly reviewed, including the use of equilibrium statistical mechanics to predict behavior of long-lived coherent structures, and the controversial maximum entropy production principle.