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Siberian 2020 heatwave increased spring CO2 uptake but not annual CO2 uptake
Siberia experienced an unprecedented strong and persistent heatwave in winter to spring of 2020. Using bottom–up and top–down approaches, we evaluated seasonal and annual CO _2 fluxes of 2020 in the northern hemisphere (north of 30 °N), focusing on Siberia where the pronounced heatwave occurred. We found that, over Siberia, CO _2 respiration loss in response to the pronounced positive winter temperature anomaly was greater than in previous years. However, continued warming in the spring enhanced photosynthetic CO _2 uptake, resulting in the largest seasonal transition in net ecosystem CO _2 exchange; that is, the largest magnitude of the switch from the net CO _2 loss in winter to net CO _2 uptake in spring until June. However, this exceptional transition was followed by the largest reduction in CO _2 uptake in late summer due to multiple environmental constraints, including a soil moisture deficit. Despite a substantial increase of CO _2 uptake by 22 ± 9 gC m ^−2 in the spring in response to the heatwave, the mean annual CO _2 uptake over Siberia was slightly lower (3 ± 13 gC m ^−2 yr ^−1 ) than the average of the previous five years. These results highlight the highly dynamic response of seasonal carbon fluxes to extreme temperature anomalies at high latitudes, indicating a seasonal compensation between abnormal uptake and release of CO _2 in response to extreme warmth that may limit carbon sink capacity in high northern latitudes.
Siberian 2020 heatwave increased spring CO2 uptake but not annual CO2 uptake
Siberia experienced an unprecedented strong and persistent heatwave in winter to spring of 2020. Using bottom–up and top–down approaches, we evaluated seasonal and annual CO _2 fluxes of 2020 in the northern hemisphere (north of 30 °N), focusing on Siberia where the pronounced heatwave occurred. We found that, over Siberia, CO _2 respiration loss in response to the pronounced positive winter temperature anomaly was greater than in previous years. However, continued warming in the spring enhanced photosynthetic CO _2 uptake, resulting in the largest seasonal transition in net ecosystem CO _2 exchange; that is, the largest magnitude of the switch from the net CO _2 loss in winter to net CO _2 uptake in spring until June. However, this exceptional transition was followed by the largest reduction in CO _2 uptake in late summer due to multiple environmental constraints, including a soil moisture deficit. Despite a substantial increase of CO _2 uptake by 22 ± 9 gC m ^−2 in the spring in response to the heatwave, the mean annual CO _2 uptake over Siberia was slightly lower (3 ± 13 gC m ^−2 yr ^−1 ) than the average of the previous five years. These results highlight the highly dynamic response of seasonal carbon fluxes to extreme temperature anomalies at high latitudes, indicating a seasonal compensation between abnormal uptake and release of CO _2 in response to extreme warmth that may limit carbon sink capacity in high northern latitudes.
Siberian 2020 heatwave increased spring CO2 uptake but not annual CO2 uptake
Min Jung Kwon (author) / Ashley Ballantyne (author) / Philippe Ciais (author) / Ana Bastos (author) / Frédéric Chevallier (author) / Zhihua Liu (author) / Julia K Green (author) / Chunjing Qiu (author) / John S Kimball (author)
2021
Article (Journal)
Electronic Resource
Unknown
Metadata by DOAJ is licensed under CC BY-SA 1.0
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