Abstract
Methane (CH4) is a potent greenhouse gas (GHG) that affects the global climate system. Knowledge about land–atmospheric CH4 exchanges on the Qinghai-Tibetan Plateau (QTP) is insufficient. Using a coupled biogeochemistry model, this study analyzes the net exchanges of CH4 and CO2 over the QTP for the period of 1979–2100. Our simulations show that the region currently acts as a net CH4 source with 0.95 Tg CH4 y−1 emissions and 0.19 Tg CH4 y−1 soil uptake, and a photosynthesis C sink of 14.1 Tg C y−1. By accounting for the net CH4 emission and the net CO2 sequestration since 1979, the region was found to be initially a warming source until the 2010s with a positive instantaneous radiative forcing peak in the 1990s. In response to future climate change projected by multiple global climate models (GCMs) under four representative concentration pathway (RCP) scenarios, the regional source of CH4 to the atmosphere will increase by 15–77% at the end of this century. Net ecosystem production (NEP) will continually increase from the near neutral state to around 40 Tg C y−1 under all RCPs except RCP8.5. Spatially, CH4 emission or uptake will be noticeably enhanced under all RCPs over most of the QTP, while statistically significant NEP changes over a large-scale will only appear under RCP4.5 and RCP4.6 scenarios. The cumulative GHG fluxes since 1979 will exert a slight warming effect on the climate system until the 2030s, and will switch to a cooling effect thereafter. Overall, the total radiative forcing at the end of the 21st century is 0.25–0.35 W m−2, depending on the RCP scenario. Our study highlights the importance of accounting for both CH4 and CO2 in quantifying the regional GHG budget.
Highlights
Methane (CH4), second only to carbon dioxide (CO2), is an important greenhouse gas (GHG) that is responsible for about 20% of the global warming induced by human activity since preindustrial times (IPCC, 2013)
Both the soil thermal model (STM) and methane dynamics module (MDM) outputs were able to reproduce the seasonal dynamics of the observed daily soil temperature and CH4 fluxes
The adjusted R2 and RMSE for the soil temperature simulated with the optimal STM are 0.95 and 1.88 °C, respectively
Summary
Methane (CH4), second only to carbon dioxide (CO2), is an important greenhouse gas (GHG) that is responsible for about 20% of the global warming induced by human activity since preindustrial times (IPCC, 2013). Because CH4 has a much higher global warming potential (GWP) than CO2 in a time horizon of 100 years, and actively interacts with aerosols and ozone (Shindell et al 2009), even small changes in atmospheric CH4 concentration will have profound impacts on the future climate (Bridgham et al 2013, Zhuang et al 2013). Among all natural sources of CH4, global wetlands are the single largest source that is responsible for emissions of 142–284 Tg CH4 per year (Kirschke et al 2013, Wania et al 2013). The relative strength of sources and sinks determines the global net CH4 emission on various spatial or temporal scales
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