A Major Improvement of Atmospheric Wave Boundary Layer Model for Storm Surge Modeling by Including Effect of Wave Breaking on Air-Sea Momentum Exchange

Journal of Physical Oceanography Pub Date : 2024-03-20 DOI:10.1175/jpo-d-23-0233.1

Anyifang Zhang, Xiping Yu

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Abstract

Accurate estimation of the wind stress under extreme conditions is crucial for modeling storm surges and storm waves, which is important to the development of a warning system for coastal disaster prevention. The problem, however, is highly challenging owing to the presence of complex ocean surface processes under the action of unusually strong wind. In this study, the existing atmospheric wave boundary layer model is significantly enhanced by including various effects of wave breaking. Both the effect of wave breaking on the dissipation of energy and its effect on the transfer of momentum within the atmospheric boundary layer are carefully formulated. The wind stress coefficients obtained with the enhanced model are shown to be in good agreement with the measurements in not only deep but also shallow waters. The enhanced atmospheric wave boundary layer model is coupled with ocean wave as well as circulation models to simulate typhoon-induced storm surges and storm waves in the Pearl River Delta region. The computational results show that the coupled model with improved evaluation of the wind stress is substantially advantageous when compared with existing approaches.

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通过纳入破浪对海气动量交换的影响，对用于风暴潮建模的大气波浪边界层模型进行重大改进

准确估算极端条件下的风应力，对于风暴潮和海浪的建模至关重要，这对开发沿海灾害预防预警系统也很重要。然而，由于异常强风作用下存在复杂的海面过程，这一问题具有很高的挑战性。在本研究中，现有的大气波浪边界层模型通过加入各种破浪效应得到了显著增强。破浪对能量耗散的影响及其对大气边界层内动量传递的影响都得到了细致的阐述。结果表明，用增强模型得到的风应力系数与深水和浅水的测量结果都非常吻合。增强型大气波浪边界层模式与海洋波浪和环流模式耦合，模拟了珠江三角洲地区由台风引起的风暴潮和风暴波。计算结果表明，与现有方法相比，改进了风应力评估的耦合模型具有很大优势。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Physical Oceanography

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