On detecting biospheres from chemical thermodynamic disequilibrium in planetary atmospheres

TL;DR

This paper introduces a thermodynamic approach to detect biospheres by measuring chemical disequilibrium in planetary atmospheres, emphasizing Earth's unique disequilibrium due to life and providing a potential universal biosignature method.

Contribution

It provides the first rigorous calculations of atmospheric chemical disequilibrium in the Solar System, including multiphase effects, and discusses its potential as an exoplanet biosignature.

Findings

Earth's atmosphere-ocean disequilibrium is vastly larger than other planets.

Biogenic processes mainly cause Earth's disequilibrium.

The disequilibrium energy on Earth is comparable to thermal energy per mole.

Abstract

Atmospheric chemical disequilibrium has been proposed as a method for detecting extraterrestrial biospheres from exoplanet observations. Chemical disequilibrium is potentially a generalized biosignature since it makes no assumptions about particular biogenic gases or metabolisms. Here, we present the first rigorous calculations of the thermodynamic chemical disequilibrium in Solar System atmospheres, in which we quantify the available Gibbs energy: the Gibbs free energy of an observed atmosphere minus that of atmospheric gases reacted to equilibrium. The purely gas phase disequilibrium in Earth's atmosphere is mostly attributable to O2 and CH4. The available Gibbs energy is not unusual compared to other Solar System atmospheres and smaller than that of Mars. However, Earth's fluid envelope contains an ocean, allowing gases to react with water and requiring a multiphase calculation with aqueous species. The disequilibrium in Earth's atmosphere-ocean system (in joules per mole of atmosphere) ranges from 20 to 2E6 times larger than the disequilibria of other atmospheres in the Solar System. Only on Earth is the chemical disequilibrium energy comparable to the thermal energy per mole of atmosphere. Earth's disequilibrium is biogenic, mainly caused by the coexistence of N2, O2 and liquid water instead of more stable nitrate. In comparison, the O2-CH4 disequilibrium is minor. We identify abiotic processes that cause disequilibrium in the other atmospheres. Our metric requires minimal assumptions and could potentially be calculated using observations of exoplanet atmospheres. However, further work is needed to establish whether thermodynamic disequilibrium is a practical exoplanet biosignature, requiring an assessment of false positives, noisy observations, and other detection challenges. Our Matlab code and databases for these calculations are available, open source.