Topological mechanical metamaterials: A brief review

•Introduce concepts of topological mechanical metamaterials.•Retrospect recent researches on topological mechanical metamaterials.•Review topological mechanical phases with zero/finite frequencies.•Provide useful perspectives on topological mechanical metamaterials. Topological mechanical metamateri...

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Bibliographic Details
Published in:Current opinion in solid state & materials science 2020-10, Vol.24 (5), p.100853, Article 100853
Main Authors: Xin, Li, Siyuan, Yu, Harry, Liu, Minghui, Lu, Yanfeng, Chen
Format: Article
Language:English
Subjects:
Elastic waves
Free motion
Mechanical metamaterials
Topological phases
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Summary:•Introduce concepts of topological mechanical metamaterials.•Retrospect recent researches on topological mechanical metamaterials.•Review topological mechanical phases with zero/finite frequencies.•Provide useful perspectives on topological mechanical metamaterials. Topological mechanical metamaterials have emerged with the development of topological phases and topological phase transitions in modern condensed matter physics. Their attractive topological properties provide promising applications that are hard to achieve with traditional mechanical metamaterials, such as waveguiding without backscattering loss, vibration isolation, and free motion of structures. In this review, we briefly retrospectively examine the most flourishing works on topological mechanical metamaterials and identify the mechanisms underlying these topological mechanical phases, such as analogs to quantum Hall effects and Weyl semimetals. Topological mechanical phases are classified into two categories of t depending on their behavior when working in different frequency domains, as finite frequency properties (ω ≠ 0) are related to elastic wave propagation and zero frequency properties (ω = 0) are related to quasi-static free motion. We conclude by outlining future challenges and opportunities for the topological mechanism, and the design/fabrication and application of topological mechanical metamaterials.
ISSN:1359-0286
DOI:10.1016/j.cossms.2020.100853