海洋上层均匀层垂直混合强度的模型和实验估计

IF 0.7 Q4 OCEANOGRAPHY
A. Chukharev, M. Pavlov
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引用次数: 4

摘要

目的。本研究旨在对湍流强度的实验数据进行定性和定量分析(基于先前提出的更新的多尺度模型),并将其与理论和半经验关系进行比较,以描述各种湍流源的贡献。方法与结果。对近海面湍流特性的实验数据和模型计算结果进行了对比分析。讨论了各种物理过程对近海面湍流产生的理论评价方法。用著名的湍流交换模型计算的结果与中科院MHI湍流部科学家利用专用设备收集的实验数据进行了比较。分析结果可以确定在不同水文气象条件下应用所考虑的模型计算湍流强度的可能性。在微风中,没有一个模型得出与测量数据相符的结果。在中风条件下,模拟结果与实验数据吻合较好;对于强风,多尺度模型的结果是最好的。该模型经过修改,以评估另外两种湍流产生机制的贡献:斯托克斯漂移和朗缪尔环流。结论。客观评价湍流交换强度需要考虑湍流产生的三种主要机制,即流速剪切、波浪运动和波浪破碎。根据水文气象条件的不同,每种机制在一定的深度范围内占主导地位。利用更新后的模型进行的计算表明,Stokes漂移对30米高空的总耗散增加了2 - 17%,而通过依赖于Langmuir数的垂直动能传递速度计算的Langmuir环流的贡献在较小的Langmuir数下可以达到15%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Model and Experimental Estimates of Vertical Mixing Intensity in the Sea Upper Homogeneous Layer
Purpose. The study is aimed at qualitative and quantitative analysis (based on the updated previously proposed multiscale model) of the experimental data on turbulence intensity and their comparison with theoretical and semi-empirical relationships for the purpose of describing the contributions of various turbulence sources. Methods and Results. A comparative analysis of experimental data and model calculations of turbulence characteristics near the sea surface was performed. The methods of theoretical assessing generation of turbulence in the near-surface sea layer by various physical processes are considered. The results of calculations by the well-known models of turbulent exchange were compared with the experimental data collected by the scientists of the Turbulence Department of MHI, RAS, using the specialized equipment. The analysis results made it possible to determine the possibility of applying the considered models for calculating turbulence intensity under different hydrometeorological conditions. At light winds, none of the models yielded the results which matched the measurement data. At moderate winds, the simulation results showed quite satisfactory agreement with the experiment data; and for strong winds, the multiscale model results were the best. This model was modified to assess the contributions of two other mechanisms of turbulence generation: the Stokes drift and the Langmuir circulations. Conclusions. Objective assessment of the turbulent exchange intensity requires taking into account of three main mechanisms of turbulence generation, namely flow velocity shear, wave motions and wave breaking. Depending on the hydrometeorological situation, each of these mechanisms can dominate in a certain depth range. The calculations performed using the updated model showed that the Stokes drift added 2–17 % to the total dissipation in the upper 30-meter layer, whereas the contribution of the Langmuir circulations calculated through dependence of the vertical velocity of kinetic energy transfer upon the Langmuir number, can reach 15 % for small Langmuir numbers.
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来源期刊
Physical Oceanography
Physical Oceanography OCEANOGRAPHY-
CiteScore
1.80
自引率
25.00%
发文量
8
审稿时长
24 weeks
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