The early Earth as an analogue for exoplanetary biogeochemistry

TL;DR

This paper reviews Earth's geobiological evolution as an analogue for exoplanetary biosignature detection, emphasizing how tectonic and atmospheric changes influence biosignature visibility over Earth's history.

Contribution

It synthesizes Earth's early biogeochemical record to inform the search for biosignatures on exoplanets, highlighting the role of tectonics and planetary conditions in biosignature detectability.

Findings

Methane was likely the earliest detectable biosignature.

Oxygenic photosynthesis emerged with modern plate tectonics.

Biosignature detectability depends on tectonic and atmospheric evolution.

Abstract

Planet Earth has evolved from an entirely anoxic planet with possibly a different tectonic regime to the oxygenated world with horizontal plate tectonics that we know today. For most of this time, Earth has been inhabited by a purely microbial biosphere albeit with seemingly increasing complexity over time. A rich record of this geobiological evolution over most of Earth's history provides insights into the remote detectability of microbial life under a variety of planetary conditions. We leverage Earth's geobiological record with the aim of a) illustrating the current state of knowledge and key knowledge gaps about the early Earth as a reference point in exoplanet science research; b) compiling biotic and abiotic mechanisms that controlled the evolution of the atmosphere over time; and c) reviewing current constraints on the detectability of Earth's early biosphere with state-of-the-art telescope technology. We highlight that life may have originated on a planet with a different tectonic regime and strong hydrothermal activity, and under these conditions, biogenic CH$_4$ gas was perhaps the most detectable atmospheric biosignature. Oxygenic photosynthesis, which is responsible for essentially all O$_2$ gas in the modern atmosphere, appears to have emerged concurrently with the establishment of modern plate tectonics and the continental crust, but O$_2$ accumulation to modern levels only occurred late in Earth's history, perhaps tied to the rise of land plants. Nutrient limitation in anoxic oceans, promoted by hydrothermal Fe = fluxes, may have limited biological productivity and O$_2$ production. N$_2$O is an alternative biosignature that was perhaps significant on the redox-stratified Proterozoic Earth. We conclude that the detectability of atmospheric biosignatures on Earth was not only dependent on biological evolution but also strongly controlled by the evolving tectonic context.