YAN Yu, GU Wei, XU Yingjun, LI Qian. The in situ observation of modelled sea ice drift characteristics in the Bohai Sea[J]. Acta Oceanologica Sinica, 2019, 38(3): 17-25. doi: 10.1007/s13131-019-1395-5
Citation: YAN Yu, GU Wei, XU Yingjun, LI Qian. The in situ observation of modelled sea ice drift characteristics in the Bohai Sea[J]. Acta Oceanologica Sinica, 2019, 38(3): 17-25. doi: 10.1007/s13131-019-1395-5

The in situ observation of modelled sea ice drift characteristics in the Bohai Sea

doi: 10.1007/s13131-019-1395-5
  • Received Date: 2018-01-05
  • Sea ice drift is mainly controlled by ocean currents, local wind, and internal ice stress. Information on sea ice motion, especially in situ synchronous observation of an ice velocity, a current velocity, and a wind speed, is of great significance to identify ice drift characteristics. A sea ice substitute, the so-called "modelled ice", which is made by polypropylene material with a density similar to Bohai Sea ice, is used to complete a free drift experiment in the open sea. The trajectories of isolated modelled ice, currents and wind in the Bohai Sea during non-frozen and frozen periods are obtained. The results show that the currents play a major role while the wind plays a minor role in the free drift of isolated modelled ice when the wind is mild in the Bohai Sea. The modelled ice drift is significantly affected by the ocean current and wind based on the ice-current-wind relationship established by a multiple linear regression. The modelled ice velocity calculated by the multiple linear regression is close to that of the in situ observation, the magnitude of the error between the calculated and observed ice velocities is less than 12.05%, and the velocity direction error is less than 6.21°. Thus, the ice velocity can be estimated based on the observed current velocity and wind speed when the in situ observed ice velocity is missing. And the modelled ice of same thickness with a smaller density is more sensitive to the current velocity and the wind speed changes. In addition, the modelled ice drift characteristics are shown to be close to those of the real sea ice, which indicates that the modelled ice can be used as a good substitute of real ice for in situ observation of the free ice drift in the open sea, which helps solve time availability, safety and logistics problems related to in situ observation on real ice.
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