Global responses of wetland methane emissions to extreme temperature and precipitation.

As global warming continues, events of extreme heat or heavy precipitation will become more frequent, while events of extreme cold will become less so. How wetlands around the globe will react to these extreme events is unclear yet critical, because they are among the greatest natural sources of methane(CH 4). Here we use seven indices of extreme climate and the rate of methane emission from global wetlands(WME) during 2000–2019 simulated by 12 published models as input data. Our analyses suggest that extreme cold (particularly extreme low temperatures) inhibits WME, whereas extreme heat (particularly extreme high temperatures) accelerates WME. Our results also suggest that daily precipitation >10 mm accelerates WME, while much higher daily precipitation levels can slow WME. The correlation of extreme high temperature and precipitation with rate of WME became stronger during the study period, while the correlation between extreme low temperature and WME rate became weaker. • Quantitatively assessed the response of wetland CH 4 emissions to extreme climate globally. • Global wetland CH 4 emission rates are most sensitive to daily temperature extremes. • Precipitation stimulated emissions in general. Beyond a certain level, however, extreme precipitation inhibited emissions. • Impacts of climate extremes on wetland CH 4 emissions continue to increase significantly. [ABSTRACT FROM AUTHOR]