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The Effect of the Winter Wind Storm on Water Flux in Bohai Strait

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ã€Authorã€‘ Yu Hang;Bao Xianwen;Ding Yang;Zhou Lingling;College of Oceanic and Atmospheric Science;The Key Laboratory of Physical Oceanography, Ministry of Education, Ocean University of China;

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ã€Abstractã€‘ Based on FVCOM model, we compared seven sets of different wind field reanalysis data and used them to simulate the marine environment of the Bohai and Yellow Sea in the winter of 2017. Comparing the modelâ€™s results with the observed data, it was found that ECMWF Reanalysis V5ï¼¿1HR(hereinafter referred to as ERA5ï¼¿1HR) can optimize the hydrological environment of the Bohai and Yellow Sea in winter. During the winter storm from February 17 to February 24, 2017, it was also found that the currents in the Bohai and North Yellow Sea would outflow and inflow through the Bohai Strait with the winter storm burst and relaxation. The outflow mainly occurred in the southern and middle part of the Bohai Strait. And the inflow mainly occurred in the northern part at first, then occurred in the whole Bohai Strait. During the wind storm, the water level changes periodically. When a wind storm burst the water in the Bohai Sea would be accumulated to the southern part. At this time the sea level was high in the southern part and low in the northern part of the Bohai Sea. When the wind storm was relaxed, the sea level in the Bohai Sea was opposite. The rapid inflow and outflow process during the wind storm period significantly enhanced the water exchange in the Bohai Sea. The outflow fluxes caused by the three high-frequency wind storms processes were 18.35Ã—10~6 m~3, 32.46Ã—10~6 m~3 and 34.15Ã—10~6 m~3 respectively; The inflow fluxes are 21.11Ã—10~6 m~3, 38.69Ã—10~6 m~3 and 22.38Ã—10~6 m~3 respectively. According to the results of two controlled experiments, the wind speed is the most important factor dominating the circulation and water exchange in the Bohai Sea during the wind storms.æ›´å¤š è¿˜åŽŸ