NEMO-Bohai 1.0: a high-resolution ocean and sea ice modelling system for the Bohai Sea, China

Severe ice conditions in the Bohai Sea could cause serious harm to maritime traffic, offshore oil exploitation, aquaculture, and other economic activities in the surrounding regions. In addition to providing sea ice forecasts for disaster prevention and risk mitigation, sea ice numerical models coul...

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Bibliographic Details
Published in:Geoscientific Model Development 2022-02, Vol.15 (3), p.1269-1288
Main Authors: Yan, Yu, Gu, Wei, Gierisch, Andrea M. U, Xu, Yingjun, Uotila, Petteri
Format: Article
Language:English
Subjects:
Analysis
Annual variations
Aquaculture
Atmospheric boundary layer
Climate change
Climate studies
Economic activities
Emergency preparedness
Endangered & extinct species
Exploitation
Global temperature changes
Ice conditions
Ice cover
Ice thickness
Interannual variations
Marine ecosystems
Mathematical models
Mitigation
Modelling
Numerical models
Ocean models
Oceans
Offshore
Oil exploration
Remote sensing
Risk reduction
Salinity
Salinity effects
Salinity stratification
Satellite observation
Satellites
Sea currents
Sea ice
Sea ice forecasting
Sea ice thickness
Sea ice variations
Sea surface
Sea surface temperature
Seals
Seasonal variation
Seasonal variations
Simulation
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Summary:Severe ice conditions in the Bohai Sea could cause serious harm to maritime traffic, offshore oil exploitation, aquaculture, and other economic activities in the surrounding regions. In addition to providing sea ice forecasts for disaster prevention and risk mitigation, sea ice numerical models could help explain the sea ice variability within the context of climate change in marine ecosystems, such as spotted seals, which are the only ice-dependent animal that breeds in Chinese waters. Here, we developed NEMO-Bohai, an ocean–ice coupled model based on the Nucleus for European Modelling of the Ocean (NEMO) model version 4.0 and Sea Ice Modelling Integrated Initiative (SI3) (NEMO4.0-SI3) for the Bohai Sea. This study will present the scientific design and technical choices of the parameterizations for the NEMO-Bohai model. The model was calibrated and evaluated with in situ and satellite observations of the ocean and sea ice. The model simulations agree with the observations with respect to sea surface height (SSH), temperature (SST), salinity (SSS), currents, and temperature and salinity stratification. The seasonal variation of the sea ice area is well simulated by the model compared to the satellite remote sensing data for the period of 1996–2017. Overall agreement is found for the occurrence dates of the annual maximum sea ice area. The simulated sea ice thickness and volume are in general agreement with the observations with slight overestimations. NEMO-Bohai can simulate seasonal sea ice evolution and long-term interannual variations. Hence, NEMO-Bohai is a valuable tool for long-term ocean and ice simulations and climate change studies.
ISSN:1991-9603
1991-959X
1991-962X
1991-9603
1991-962X
DOI:10.5194/gmd-15-1269-2022