%0 Journal Article %1 pan2021cause %A Pan, Xiao %A Li, Tim %A Sun, Ying %A Zhu, Zhiwei %D 2021 %J Advances in Atmospheric Sciences %K China ENSO MyYangtzeWork casestudy dynamics %R 10.1007/s00376-021-0433-3 %T Cause of Extreme Heavy and Persistent Rainfall over Yangtze River in Summer 2020 %U https://doi.org/10.1007/s00376-021-0433-3 %X Record-breaking heavy and persistent precipitation occurred over the Yangtze River Valley (YRV) in June--July (JJ) 2020. An observational data analysis has indicated that the strong and persistent rainfall arose from the confluence of southerly wind anomalies to the south associated with an extremely strong anomalous anticyclone over the western North Pacific (WNPAC) and northeasterly anomalies to the north associated with a high-pressure anomaly over Northeast Asia. A further observational and modeling study has shown that the extremely strong WNPAC was caused by both La Niña-like SST anomaly (SSTA) forcing in the equatorial Pacific and warm SSTA forcing in the tropical Indian Ocean (IO). Different from conventional central Pacific (CP) El Niños that decay slowly, a CP El Niño in early 2020 decayed quickly and became a La Niña by early summer. This quick transition had a critical impact on the WNPAC. Meanwhile, an unusually large area of SST warming occurred in the tropical IO because a moderate interannual SSTA over the IO associated with the CP El Niño was superposed by an interdecadal/long-term trend component. Numerical sensitivity experiments have demonstrated that both the heating anomaly in the IO and the heating anomaly in the tropical Pacific contributed to the formation and maintenance of the WNPAC. The persistent high-pressure anomaly in Northeast Asia was part of a stationary Rossby wave train in the midlatitudes, driven by combined heating anomalies over India, the tropical eastern Pacific, and the tropical Atlantic.

@article{pan2021cause, abstract = {Record-breaking heavy and persistent precipitation occurred over the Yangtze River Valley (YRV) in June--July (JJ) 2020. An observational data analysis has indicated that the strong and persistent rainfall arose from the confluence of southerly wind anomalies to the south associated with an extremely strong anomalous anticyclone over the western North Pacific (WNPAC) and northeasterly anomalies to the north associated with a high-pressure anomaly over Northeast Asia. A further observational and modeling study has shown that the extremely strong WNPAC was caused by both La Ni{\~{n}}a-like SST anomaly (SSTA) forcing in the equatorial Pacific and warm SSTA forcing in the tropical Indian Ocean (IO). Different from conventional central Pacific (CP) El Ni{\~{n}}os that decay slowly, a CP El Ni{\~{n}}o in early 2020 decayed quickly and became a La Ni{\~{n}}a by early summer. This quick transition had a critical impact on the WNPAC. Meanwhile, an unusually large area of SST warming occurred in the tropical IO because a moderate interannual SSTA over the IO associated with the CP El Ni{\~{n}}o was superposed by an interdecadal/long-term trend component. Numerical sensitivity experiments have demonstrated that both the heating anomaly in the IO and the heating anomaly in the tropical Pacific contributed to the formation and maintenance of the WNPAC. The persistent high-pressure anomaly in Northeast Asia was part of a stationary Rossby wave train in the midlatitudes, driven by combined heating anomalies over India, the tropical eastern Pacific, and the tropical Atlantic.}, added-at = {2021-07-04T12:37:10.000+0200}, author = {Pan, Xiao and Li, Tim and Sun, Ying and Zhu, Zhiwei}, biburl = {https://www.bibsonomy.org/bibtex/2d805b5454be2871c348612dc68a44680/pbett}, day = 30, doi = {10.1007/s00376-021-0433-3}, interhash = {68329ebd94a4040cf30991959502f0f5}, intrahash = {d805b5454be2871c348612dc68a44680}, issn = {1861-9533}, journal = {Advances in Atmospheric Sciences}, keywords = {China ENSO MyYangtzeWork casestudy dynamics}, month = jun, timestamp = {2021-07-04T12:37:10.000+0200}, title = {Cause of Extreme Heavy and Persistent Rainfall over Yangtze River in Summer 2020}, url = {https://doi.org/10.1007/s00376-021-0433-3}, year = 2021 }