Author:
Yue Yaojie,Su Peng,Gao Yuan,Zhang Puying,Wang Ran,Zhang Anyu,Jiang Qinghua,Ma Weidong,Zhou Yuantao,Wang Jing’ai
Abstract
AbstractThe latest special report from the Intergovernmental Panel on Climate Change (IPCC), published in 2018 (Anandhi et al. 2016), estimates a 1.5 °C increase in global temperature in 2040 at the current rate of global warming. Such a rise has serious implications for major cereal crop cultivation: unless crop varieties adapted to higher temperatures become available, the areas suitable for cropping are bound to shift in the future. Therefore, to safeguard food security, we need to predict such changes in spatial and temporal terms, which can intuitively reflect the potential distribution of crops under different climate change scenarios and for different time periods, helping to reduce losses according to local conditions (Deng et al. 2009).
Publisher
Springer Nature Singapore
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