Litcius/Paper detail

Strengthened Impacts of Indian Ocean Dipole on the Yangtze Precipitation Contribute to the Extreme Rainfall of 2020 Meiyu Season

Yanxin Wang, Shanshan Wang, Fu Luo, Hao Wang

2022Journal of Geophysical Research Atmospheres15 citationsDOI

Abstract

Abstract In June‐July 2020, the Middle and Lower Yangtze River Region (MLYR) encountered the most severe precipitation event over the past 60 years. The Indian Ocean Dipole (IOD) in the previous autumn of the unusual precipitation event was the main contributing factor. Nonetheless, not every strong IOD event could bring anomalously high precipitation in the MLYR. This study showed significantly enhanced influence of IOD on East Asia climate since 2000. The IOD's effect on MLYR summer precipitation has strengthened significantly with the correlation coefficient up to 0.55 during 2000–2020. The northward movement of East Asia–Pacific pattern associated with IOD since 2000 (as compared with before) was primarily responsible for the enhanced effect. Since 2000, the MLYR has been controlled by a deep baroclinic instability system with anomalous low pressure in the lower troposphere and anomalous high pressure (completely different from before). Furthermore, the western Pacific subtropical high shifted northward and westerly jets were significantly enhanced with eastward expansion. All of these patterns contributed to the water vapor convergence and precipitation generation in the MLYR, which was not the case in the past. The record‐breaking IOD in 2019 autumn and the enhanced IOD's climatic effect in 2000–2020 contribute to the extreme Meiyu in 2020 jointly. The significant change in the influence of IOD and the enhanced climate effect of IOD highlight exciting new avenues for improving climate predictions in the MLYR.

Topics & Concepts

ClimatologyPrecipitationIndian Ocean DipoleSubtropical ridgeBaroclinityEnvironmental scienceYangtze riverTroposphereEast AsiaGeologyOceanographyGeographySea surface temperatureChinaMeteorologyArchaeologyClimate variability and modelsOceanographic and Atmospheric ProcessesTropical and Extratropical Cyclones Research