Abstract
The sea surface temperature (SST) in the South China Sea (SCS) displays prominent intraseasonal variations during boreal winter with a spectrum peak in the 10–30-day time period. These intraseasonal SST variations are closely associated with intraseasonal variations of the East Asian winter monsoon (EAWM). A weak EAWM is preceded by cooler SST and followed by warmer SST in the SCS and subtropical western North Pacific. A coherent southward propagation is seen in the SCS in SST, surface wind, and latent heat flux anomalies. This southward propagation is attributed to the wind-evaporation-SST effect under climatological northerly winds in winter, which differs from summer when climatological winds are westerly. The SST-induced wind speed anomalies are larger to the north side of SST anomalies. This induces larger surface evaporation anomalies to the north side, leading to a southward displacement of large SST anomalies. In turn, wind and evaporation anomalies move southward. There appears to be a positive feedback between circulation and precipitation that leads to amplification of meridional wind anomalies when the SST anomalies are weak. Surface latent heat flux is a dominant factor for the SST change in the SCS and the Yellow Sea. Shortwave radiation has a complementary contribution to the SST change in the SCS, but has a negative effect in the Yellow Sea. The wind-induced Ekman advection appears important for the SST warming in the Yellow Sea.
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Acknowledgements
Comments of three anonymous reviewers have helped the improvement of this paper. This study is supported by National Key Basic Research Program of China grant (2014CB953902) and National Natural Science Foundation of China grants (41475081, 41275081, and 41530425). The TMI data were obtained from http://www.remss.com/missions/tmi. The NCEP reanalysis 2 data were obtained from ftp://cdc.noaa.gov/. The GPCP precipitation data were obtained from https://climatedataguide.ucar.edu/climate-data/gpcp-daily-global-precipitation-climatology-project.
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Wu, R. Coupled intraseasonal variations in the East Asian winter monsoon and the South China Sea–western North Pacific SST in boreal winter. Clim Dyn 47, 2039–2057 (2016). https://doi.org/10.1007/s00382-015-2949-7
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DOI: https://doi.org/10.1007/s00382-015-2949-7