Abstract
Against the backdrop of global climate change, alterations in precipitation regimes-including the increasing frequency of extreme events-have become more widespread, exerting profound impacts on terrestrial ecosystems and reshaping greenhouse gas (GHG) emission dynamics in wetlands. Wetlands, as unique ecosystems formed at the interface of terrestrial and aquatic environments, play a critical role in regulating carbon source-sink functions. In this study, we conducted in situ field simulation experiments to examine how precipitation changes influence the seasonal fluxes of carbon dioxide (CO(2)), methane (CH(4)), and nitrous oxide (N(2)O) in the Wayan Mountain headwater wetlands, and further explored the regulatory effects of vegetation attributes and soil physicochemical properties on these fluxes. The results revealed that a moderate increase in precipitation (+25%) enhanced CO(2) emissions and vegetation growth while suppressing CH(4) and N(2)O fluxes, indicating a positive ecosystem response to additional water supply. In contrast, extreme precipitation changes (+75% and -75%) weakened the coupling between GHG fluxes and soil factors, resulting in reduced CO(2) flux, amplified variability in CH(4) and N(2)O emissions, and inhibited vegetation growth and community diversity. The dominant controls differed among gases: CO(2) was primarily regulated by soil carbon pools, CH(4) was highly sensitive to water availability, and N(2)O was influenced by soil nitrogen, pH, and salinity. Overall, moderate increases in precipitation enhance the carbon sink capacity and community stability of alpine wetlands, whereas extreme hydrological fluctuations undermine ecosystem functioning. These findings provide important insights into carbon cycling processes and regulatory mechanisms of alpine wetlands under future climate change scenarios.