在冰雪覆盖的北冰洋中传播的波的频散性

IF 2.3 3区 地球科学 Q2 OCEANOGRAPHY
Shengxing Liu , Qitian Zeng , Liguo Tang , Zhenglin Li
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引用次数: 0

摘要

北冰洋被模拟为冰-海水-沉积物系统,其中冰盖和海水被假定分别为非均质固体和液体,而沉积物被假定为均质液体。推导出了薄固层和薄液层下表面与上表面位移和应力的传递矩阵。此外,还利用传递矩阵技术推导出了在冰雪覆盖的北冰洋中传播的波的频散方程。通过对频散方程进行数值求解,得到了相速和群速频散曲线。结果表明,有冰覆盖的北冰洋的频散曲线要比无冰覆盖的复杂得多。除新模式外,n-th(n >2)模式的相位速度曲线表现出轻微的扭曲,导致群速度曲线出现一个尖锐的峰值。这些峰值取决于模式的阶数,可能大大高于海水中的声速。冰盖厚度的变化对第一和第二模态的频散曲线有显著影响。此外,还研究了海水深度对频散曲线的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dispersion of waves propagating in the ice-covered Arctic Ocean

The Arctic Ocean was modeled as an ice–seawater–sediment system, where the ice cover and seawater were assumed to be inhomogeneous solid and liquid, respectively, while the sediment was assumed to be homogeneous liquid. Transfer matrixes relating the displacements and stresses at the lower surface and those at the upper surface for a thin solid layer, and a thin liquid layer were derived. Furthermore, a dispersion equation for waves propagating in the ice-covered Arctic Ocean was derived using the transfer matrix technique. The phase- and group-velocity dispersion curves were obtained by solving the dispersion equation numerically. The results show that the dispersion curves for the Arctic Ocean with ice cover are much more complex than those without ice cover. Except for the new mode, the phase-velocity curve for the n-th (n > 2) mode exhibited a slight distortion, which caused a sharp peak in the group-velocity curve. These peak values, which depend on the order of the mode, may be significantly higher than the speed of sound in seawater. The variation of the ice cover thickness had significant influence on the dispersion curves of the first and second modes. Moreover, the influence of the seawater depth on the dispersion curves were investigated.

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来源期刊
CiteScore
4.60
自引率
4.20%
发文量
144
审稿时长
18.3 weeks
期刊介绍: Deep-Sea Research Part I: Oceanographic Research Papers is devoted to the publication of the results of original scientific research, including theoretical work of evident oceanographic applicability; and the solution of instrumental or methodological problems with evidence of successful use. The journal is distinguished by its interdisciplinary nature and its breadth, covering the geological, physical, chemical and biological aspects of the ocean and its boundaries with the sea floor and the atmosphere. In addition to regular "Research Papers" and "Instruments and Methods" papers, briefer communications may be published as "Notes". Supplemental matter, such as extensive data tables or graphs and multimedia content, may be published as electronic appendices.
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