Abstract
Potential changes in both the intensity and frequency of extreme drought events are vital aspects of regional climate change that can alter the distribution and dynamics of water availability and subsequently affect carbon cycles at the ecosystem level. The effects of extreme drought events on the carbon budget of peatland in the Zoige plateau and its response mechanisms were studied using an in-field controlled experimental method. The results indicated that the peatland ecosystem of the Zoige plateau functioned as a carbon sink while under the control (CK) or extreme drought (D) treatment throughout the entire growing season. Maximum fluxes of methane (CH4) emissions and the weakest carbon sink activity from this ecosystem were in the early growth stage, the most powerful carbon sink activity was during the peak growth stage, while the absorption sink activity of carbon dioxide (CO2) and CH4 was present during the senescence stage. Extreme drought reduced the gross primary productivity (GPP) and ecosystem respiration (Re) of the peatland ecosystem by 14.5% and 12.6%, respectively (p < 0.05) and the net ability to store carbon was reduced by 11.3%. Overall, the GPP was highly sensitive to extreme drought. Moreover, extreme drought significantly reduced the CH4 fluxes of the ecosystem and even changed the peatland from a CH4 emission source to a CH4 sink. Subsequent to drought treatment, extreme drought was also shown to have a carry-over effect on the carbon budget of this ecosystem. Soil water content and soil temperature were the main driving factors of carbon budget change in the peatland of the Zoige plateau, but with the increase in soil depth, these driving forces were decreased. The findings indicated that frequent extreme drought events in the future might reduce the net carbon sink function of peatland areas, with an especially strong influence on CO2.
Highlights
The latest assessment report released by the United Nations Intergovernmental Panel on Climate Change (IPCC) shows that the intensification of human activity has dramatically changed the global pattern of the atmospheric cycle
Hydrothermal Conditions During the controlled experimental drought period, there werDeusriixngntahteucroanltrporlelecdipeixtpaetiroimneenvtaelndtrso(uFgihgtupreeri2o)d.t,htihserpeeriod was iwnetrhe esixrannagtueraolfp0re.1c–ip2i7tatmiomn e, vaenndts t(hFiegutoreta2l).pTrheecidpaiitlaytpiorneciwpiatasti6o7n.9dumrimng, twhihs ipcehriowdaws ams uincthhelower than rthanagt eoof fth0.e1–a2v7ermamge, apnrdectihpeittaottiaolnproevceiprittahteioanssweassse6d7.930m-yme,awr htiimchewpaesrimoduc(h11lo6w.1emr tmha)n
The goal of this study was to investigate how carbon budgets were affected by extreme drought events in the Zoige alpine peatland
Summary
The latest assessment report released by the United Nations Intergovernmental Panel on Climate Change (IPCC) shows that the intensification of human activity has dramatically changed the global pattern of the atmospheric cycle. Extreme drought events change key processes in the water cycle, and subsequently affect the carbon and nitrogen cycling processes of an ecosystem, breaking the original carbon sink pattern and causing changes in the structure and function of terrestrial ecosystems [6,7,8]. This significantly affects the trends and intensity of global climate change [9]. Previous studies have mostly focused on the response of carbon source/sink functions in ecosystems relative to long-term trends in climate change and have neglected the impact of short-term extreme drought events and their mechanisms [2,13], restricting the ability to understand and predict the ecological consequences of climate change and to adopt adaptive countermeasures
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
