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According to statistic analysis on sea surface temperature(SST)anomaly features in theNorth Pacific in winters and springs prior to the summer flood/drought in the middle and lowerreaches of the Yangtze River(hereafter referred to as MLRY),a strong signal SST key area thataffects local flood/drought is put forward,that is the equatorial eastern Pacific.The response ofgeneral circulation in the Northern Hemisphere to SST anomaly in the key area is furtherinvestigated. The low frequency wave train structure of correlation between the eastern PacificSST and the height at 500 hPa in the Northern Hemisphere is also studied,which reflects thedynamic features of teleresponse of local flood/drought at extratropics to tropical SST anomaly.Through introducing SST anomaly in the strong signal area in numerical experiments,the flood inYangtze River Valley is successfully simulated and the similar wave train pattern in the flow field isobtained too.Altogether,the physical picture and dynamic mode of the flood in the Yangtze RiverValley are described in this work.
According to statistic analysis on sea surface temperature (SST) anomaly features in the North Pacific in winters and springs prior to the summer flood / drought in the middle and lower reaches of the Yangtze River (hereafter referred to as MLRY), a strong signal SST key area thataffects local flood / drought is put forward, that is the equatorial eastern Pacific. The response ofgeneral circulation in the Northern Hemisphere to SST anomaly in the key area is further investigated. The low frequency wave train structure of correlation between the eastern PacificSST and the height at 500 hPa in the Northern Hemisphere is also studied, which reflects the dynamic features of teleresponse of local flood / drought at extratropics to tropical SST anomaly. Through SST anomaly in the strong Signal area in numerical experiments, the flood in Yangtze River Valley is successfully simulated and the similar wave train pattern in the flow field isobtained too. Altogether, the physical picture and dynamic mode o f the flood in the Yangtze River Valley are described in this work.