TY - JOUR
T1 - Negative Asymmetric Response of Pantropical Gross Primary Productivity to Precipitation Anomalies
AU - Fan, Lei
AU - Dong, Guanyu
AU - Ciais, Philippe
AU - Xiao, Xiangming
AU - Xiao, Jingfeng
AU - Chen, Xiuzhi
AU - Luo, Yiqi
AU - Niu, Shuli
AU - Jiang, Fei
AU - Frappart, Frédéric
AU - Wigneron, Jean-Pierre
AU - Li, Xing
AU - Cui, Tianxiang
AU - Pan, Li
AU - Fensholt, Rasmus
N1 - Publisher Copyright:
© 2024. The Author(s).
PY - 2024
Y1 - 2024
N2 - The carbon sink in pantropical biomes play a crucial role in modulating the inter-annual variations of global terrestrial carbon balance and is threatened by extreme climate events. However, it has not been carefully examined whether an increase in tropical gross primary productivity (GPP) can compensate the decrease during precipitation anomalies. Using the asymmetry index (AI) and multiple GPP products, we assessed responses of pantropical GPP to precipitation anomalies during 2001–2022. Positive AI indicates that GPP increases are greater than GPP decreases during precipitation anomalies, and vice versa. Our results showed an average negative pantropical GPP asymmetry, that is, GPP decreases exceeded the GPP increases during precipitation anomalies. In addition, a positive AI was found in tropical hyper-arid and arid regions, which is opposite to the negative AI observed in tropical semi-arid, sub-humid, and humid regions. This suggest that tropical GPP asymmetry changes from positive to negative as the moisture increases. Notably, a significant decreasing trend of negative AI was observed over the entire tropical region, indicating that the negative effect of inter-annual precipitation variations on pantropical vegetation productivity has enhanced. Considering the model predicted increasing climate variability and extremes, the negative impact of precipitation variability on tropical carbon cycle may continue to intensify. Lastly, the divergence in AI estimates among multiple GPP products highlight the need to further improve our understanding of the response of tropical carbon cycle to climate changes, especially for the tropical humid regions.
AB - The carbon sink in pantropical biomes play a crucial role in modulating the inter-annual variations of global terrestrial carbon balance and is threatened by extreme climate events. However, it has not been carefully examined whether an increase in tropical gross primary productivity (GPP) can compensate the decrease during precipitation anomalies. Using the asymmetry index (AI) and multiple GPP products, we assessed responses of pantropical GPP to precipitation anomalies during 2001–2022. Positive AI indicates that GPP increases are greater than GPP decreases during precipitation anomalies, and vice versa. Our results showed an average negative pantropical GPP asymmetry, that is, GPP decreases exceeded the GPP increases during precipitation anomalies. In addition, a positive AI was found in tropical hyper-arid and arid regions, which is opposite to the negative AI observed in tropical semi-arid, sub-humid, and humid regions. This suggest that tropical GPP asymmetry changes from positive to negative as the moisture increases. Notably, a significant decreasing trend of negative AI was observed over the entire tropical region, indicating that the negative effect of inter-annual precipitation variations on pantropical vegetation productivity has enhanced. Considering the model predicted increasing climate variability and extremes, the negative impact of precipitation variability on tropical carbon cycle may continue to intensify. Lastly, the divergence in AI estimates among multiple GPP products highlight the need to further improve our understanding of the response of tropical carbon cycle to climate changes, especially for the tropical humid regions.
KW - climate extremes
KW - non-linear response
KW - tropical carbon cycle
KW - vegetation productivity
U2 - 10.1029/2024EF004760
DO - 10.1029/2024EF004760
M3 - Journal article
AN - SCOPUS:85206672336
VL - 12
JO - Earth's Future
JF - Earth's Future
SN - 2328-4277
IS - 10
M1 - e2024EF004760
ER -