Abstract
The rewetting of dry soils by rainfall pulses boosts the release of greenhouse gases over a short time period and is the primary pathway for greenhouse gas emissions in dryland ecosystems. However, the intrinsic mechanisms underlying such emission pulses of greenhouse gases are not clear, especially in areas covered by biological soil crusts with strong microbial activity. Here, we simulated rain events in bareland, cyanobacteria/lichen, and moss crusted soil using triple isotope labeling (13C, 15N, and 18O) to explore the sources of the hydroxyl radical (·OH) and their effects on greenhouse gas production. We found that the ·OH was produced after a rainfall event via rapid activation of microorganisms in the soils. The carbon dioxide (CO2) and nitrous oxide (N2O) production significantly decreased after ·OH removal, whereas the methane (CH4) production was not affected. We revealed that ·OH synergy with enzymatic reactions of microorganisms increased CO2 production from the soil by 25%. The ·OH also stimulated the conversion of NH4+ to NO3− and dominated the N2O production (80%). Our results confirm the pivotal role of ·OH in the production of greenhouse gases and indicate that microbially mediated ·OH oxidation mechanisms are an overlooked dominated pathway for the emission of greenhouse gases in dryland ecosystems.