1. Spring photosynthetic phenology of Chinese vegetation in response to climate change and its impact on net primary productivity.
- Author
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Xue, Yingying, Bai, Xiaoyong, Zhao, Cuiwei, Tan, Qiu, Li, Yangbing, Luo, Guangjie, Wu, Luhua, Chen, Fei, Li, Chaojun, Ran, Chen, Zhang, Sirui, Liu, Min, Gong, Suhua, Xiong, Lian, Song, Fengjiao, Du, Chaochao, Xiao, Biqin, Li, Zilin, and Long, Mingkang
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CLIMATE change , *SPRING , *PLANT phenology , *PHENOLOGY , *CHLOROPHYLL spectra , *TEMPERATURE control - Abstract
• Average start of the photosynthetic period in China was on the 123rd day of the year. • The average start of the photosynthetic period advances at a rate of 4.3 d (10 a)−1. • 64% of the region is temperature controlled, others are precipitation controlled. • Importance of temperature and precipitation determined by pre-season precipitation. • Climate change increases NPP by advancing the start of the photosynthetic period. In the context of global warming, the advancement of spring phenology in northern and temperate regions due to increased temperatures has been widely reported. Early and delayed start of the photosynthetic period (SOP) directly affects the vegetation net primary productivity (NPP). However, the interrelationship between climate change, the SOP, and the NPP is unclear. In this paper, we use the dynamics of decadal daily solar-induced chlorophyll fluorescence data to calculate the response of Chinese vegetation photosynthetic phenology to climate change and its impact on the NPP over the last 20 years. The results found that over the last 20 years, the average SOP in China was on the 123rd day of the year, and the SOP has advanced at an average rate of 4.3 d (10 a)−1, with a faster trend of SOP advancement in highland and high-altitude areas. 64% of SOP in China is controlled by temperature; 36% of the SOP in China is controlled by precipitation, and the relative importance of temperature and precipitation was reversed as the precipitation gradient decreased, with SOP dominated by temperature when pre-season precipitation ≧300 mm, and SOP dominated by precipitation when pre-season precipitation ≦300 mm. Finally, we find that climate change indirectly increases vegetation NPP by advancing SOP. Our study emphasizes the importance of precipitation on phenology. It provides a scientific basis for understanding and predicting the response of spring photosynthetic phenology to climate change and the contribution of spring phenology to carbon estimation in terrestrial ecosystems. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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