Disequilibrium biosignatures over Earth history and implications for detecting exoplanet life

TL;DR

This paper investigates how atmospheric chemical disequilibrium on Earth has evolved over geological time and discusses its implications for detecting biosignatures on exoplanets through remote spectroscopy.

Contribution

It provides the first estimates of atmospheric disequilibrium during Earth's Precambrian, linking disequilibrium levels to the presence of life and potential biosignatures on exoplanets.

Findings

Disequilibrium increased with oxygen rise over Earth's history.

Proterozoic and Phanerozoic atmospheres may have detectable biogenic disequilibria.

Archean disequilibrium could be detectable via specific gas coexistences.

Abstract

Chemical disequilibrium in planetary atmospheres has been proposed as a generalized method for detecting life on exoplanets through remote spectroscopy. Among solar system planets with substantial atmospheres, the modern Earth has the largest thermodynamic chemical disequilibrium due to the presence of life. However, how this disequilibrium changed over time and, in particular, the biogenic disequilibria maintained in the anoxic Archean or less oxic Proterozoic eons are unknown. We calculate the atmosphere-ocean disequilibrium in the Precambrian using conservative proxy- and model-based estimates of early atmospheric and oceanic compositions. We omit crustal solids because subsurface composition is not detectable on exoplanets, unlike above-surface volatiles. We find that (i) disequilibrium increased through time in step with the rise of oxygen; (ii) both the Proterozoic and Phanerozoic may have had remotely detectable biogenic disequilibria due to the coexistence of O$_{2}$, N$_{2}$, and liquid water; and (iii) the Archean had a biogenic disequilibrium caused by the coexistence of N$_2$, CH$_4$, CO$_2$, and liquid water, which, for an exoplanet twin, may be remotely detectable. On the basis of this disequilibrium, we argue that the simultaneous detection of abundant CH$_{4}$ and CO$_{2}$ in a habitable exoplanet's atmosphere is a potential biosignature. Specifically, we show that methane mixing ratios greater than 0.001 are potentially biogenic, whereas those exceeding 0.01 are likely biogenic due to the difficulty in maintaining large abiotic methane fluxes to support high methane levels in anoxic atmospheres. Biogenicity would be strengthened by the absence of abundant CO, which should not coexist in a biological scenario.