极弹性材料的瑞利表面波

Yu Wei, Yi Chen, Wen Cheng, Xiaoning Liu, Gengkai Hu
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引用次数: 0

摘要

极端弹性材料是指一类特殊的弹性材料,其弹性矩阵显示出一个或多个零特征值,从而产生原则上不耗费能量的软变形模式。由于具有软模式,极端弹性材料具有传统固体所不具备的奇特体波特性,为操纵体波提供了前所未有的机会,例如充当弹性波的声子偏振器或水下声波的隐形斗篷。尽管瑞利表面波具有很大的潜力,但它与这种极弹性材料的体波行为有着至关重要的联系,迄今为止,人们在很大程度上仍未对其进行探索。本文基于连续体理论从理论上研究了瑞利波在极弹性材料中的传播,并利用基于泛谱结构设计的微结构超材料验证了我们的发现。这项研究为探索极弹性材料中的表面波提供了一个连续模型,并可刺激极弹性材料在控制表面波方面的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Rayleigh surface waves of extremal elastic materials
Extremal elastic materials here refer to a specific class of elastic materials whose elastic matrices exhibit one or more zero eigenvalues, resulting in soft deformation modes that, in principle, cost no energy. They can be approximated through artificially designed solid microstructures. Extremal elastic materials have exotic bulk wave properties unavailable with conventional solids due to the soft modes, offering unprecedented opportunities for manipulating bulk waves, e.g., acting as phonon polarizers for elastic waves or invisibility cloaks for underwater acoustic waves. Despite their potential, Rayleigh surface waves, crucially linked to bulk wave behaviors of such extremal elastic materials, have largely remained unexplored so far. In this paper, we theoretically investigate the propagation of Rayleigh waves in extremal elastic materials based on continuum theory and verify our findings with designed microstructure metamaterials based on pantographic structures. Dispersion relations and polarizations of Rayleigh waves in extremal elastic materials are derived, and the impact of higher order gradient effects is also investigated by using strain gradient theory. This study provides a continuum model for exploring surface waves in extremal elastic materials and may stimulate applications of extremal elastic materials for controlling surface waves.
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