Abstract
Atmospheric methane is rapidly lost when it enters humid subterranean critical and vadose zones (e.g., air in soils and caves). Because methane is a source of carbon and energy, it can be consumed by methanotrophic methane-oxidizing bacteria. As an additional subterranean sink, it has been hypothesized that methane is oxidized by natural radioactivity-induced radiolysis that produces energetic ions and radicals, which then trigger abiotic oxidation and consumption of methane within a few hours. Using controlled laboratory experiments, we tested whether radiolysis could rapidly oxidize methane in sealed air with different relative humidities while being exposed to elevated levels of radiation (more than 535 kBq m-3) from radon isotopes 222Rn and 220Rn (i.e., thoron). We found no evidence that radiolysis contributed to methane oxidation. In contrast, we observed the rapid loss of methane when moist soil was added to the same apparatus in the absence of elevated radon abundance. Together, our findings are consistent with the view that methane oxidizing bacteria are responsible for the widespread observations of methane depletion in subterranean environments. Further studies are needed on the ability of microbes to consume trace amounts of methane in poorly ventilated caves, even though the trophic and energetic benefits become marginal at very low partial pressures of methane.
Highlights
Energetic radiation generates ions and radicals in fluids via radiolysis that can trigger subsequent chemical reactions [1], including the oxidation of organics
Few studies have addressed the quantitative importance of radiolysis for contemporary fluxes in the atmosphere and the critical zone, especially in comparison to processes that compete with biologically mediated transformations
(RHUL) was supported by the Spanish Ministry of Economy and Competitiveness projects CGL201678318-C2-1R and CGL2016-78318-C2-2R AEI/ FEDER/UE awarded to Angel Fernandez-Cortes
Summary
Energetic radiation generates ions and radicals in fluids via radiolysis that can trigger subsequent chemical reactions [1], including the oxidation of organics. Radiolysis has likely affected the evolution of early microbial metabolisms and is crucial for powering the deep microbial biosphere [2, 3]. Few studies have addressed the quantitative importance of radiolysis for contemporary fluxes in the atmosphere and the critical zone, especially in comparison to processes that compete with biologically mediated transformations. (RHUL) was supported by the Spanish Ministry of Economy and Competitiveness projects CGL201678318-C2-1R and CGL2016-78318-C2-2R AEI/ FEDER/UE awarded to Angel Fernandez-Cortes. Angel Fernandez-Cortes’ work was further supported by project SMACKS (IEFMarie Curie Actions no 624204, FP7/2007-2013). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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