Hypotheses for near-surface exchange of methane on Mars

TL;DR

This paper proposes three hypotheses involving near-surface reservoirs, microbial activity, and deep aquifers to explain episodic methane spikes detected by the Curiosity rover on Mars, challenging current geological models.

Contribution

It introduces testable hypotheses linking methane variability to near-surface processes, microbial activity, and subsurface sources, expanding understanding of Martian methane dynamics.

Findings

Methane spikes correlate with deliquescence of perchlorate salts.

Adsorption energy needed exceeds laboratory measurements.

Microbial conversion of organics could produce methane.

Abstract

The Curiosity rover recently detected a background of 0.7 ppb and spikes of 7 ppb of methane on Mars. This in situ measurement reorients our understanding of the Martian environment and its potential for life, as the current theories do not entail any geological source or sink of methane that varies sub-annually. In particular, the 10-fold elevation during the southern winter indicates episodic sources of methane that are yet to be discovered. Here we suggest a near-surface reservoir could explain this variability. Using the temperature and humidity measurements from the rover, we find that perchlorate salts in the regolith deliquesce to form liquid solutions, and deliquescence progresses to deeper subsurface in the season of the methane spikes. We therefore formulate the following three testable hypotheses. The first scenario is that the regolith in Gale Crater adsorbs methane when dry and releases this methane to the atmosphere upon deliquescence. The adsorption energy needs to be 36 kJ/mol to explain the magnitude of the methane spikes, higher than existing laboratory measurements. The second scenario is that microorganisms convert organic matter in the soil to methane when they are in liquid solutions. This scenario does not require regolith adsorption, but entails extant life on Mars. The third scenario is that deep subsurface aquifers produce the bursts of methane. Continued in situ measurements of methane and water, as well as laboratory studies of adsorption and deliquescence, will test these hypotheses and inform the existence of the near-surface reservoir and its exchange with the atmosphere.