image: The schematic of the precipitation in the wet and dry seasons and the annual range with the additional 0.5? of warming. view more
Credit: Ziming Chen
The Paris Agreement in 2015 proposed a target to limit global warming to less than 2°C and pursue efforts to limit warming to less than 1.5°C. Since then, great efforts have been devoted to exploring the impacts of the 1.5°C and 2°C warming scenarios.
A recent work published in Earth's Future by a team of researchers from the Institute of Atmospheric Physics (IAP) at the Chinese Academy of Sciences has found that the seasonal cycle of precipitation is likely to enhance at stabilized 1.5°C and 2°C warming scenarios.
"Based on the output data of the Community Earth System Model low-warming experiment, we conclude that the enhancement is mainly caused by the increase in water vapor," said Ziming Chen, the first author of the study and a doctoral student from IAP.
The intensity of seasonal cycle is defined as the difference in precipitation between wet and dry seasons, representing the contrast of precipitation within a year. The wet and dry seasons are usually fixed as June to August and December to February, respectively, in the Northern Hemisphere and vice versa in the Southern Hemisphere. Neither the spatial distinction nor the temporal shifts in the wet and dry seasons have previously been considered.
"In our study, the intensity of the seasonal cycle is represented by the difference between mean precipitation in the wet and dry seasons for different regions and for each year," said Chen.
CHEN and his collaborators in IAP found that based on the above metric, the intensity of seasonal cycle would enhance by 3.90% and 5.27% under 1.5°C and 2°C warming. Under the additional 0.5°C of warming, a pronounced enhancement in seasonal cycle occurred over 22% of the land regions.
The enhancement was associated with the enhanced precipitation during wet season, caused by thermodynamic responses due to the increased moisture. It indicated that the contrast between the wet and dry seasons would become stronger, resulting in a more uneven distribution of freshwater resources within a year. The probability of flooding would increase in the wet season.
"This study emphasizes the pronounced enhancement in seasonal cycle over land regions associated with the additional 0.5°C warming, despite the insignificant increases in the annual precipitation," added Chen. "Though the number in temperature seems small, 0.5°C still matters."
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The work was supported by the National Natural Science Foundation of China and the National Key Research and Development Program of China.