拓扑(电路)
物理
齐次空间
拓扑绝缘体
超材料
领域(数学)
对称(几何)
边界(拓扑)
空格(标点符号)
宽带
旋转(数学)
平面波
经典力学
边值问题
理论物理学
扭转
色散(光学)
连接(主束)
混合(物理)
拓扑缺陷
路径(计算)
平面(几何)
开发(拓扑)
互惠的
极化子
作者
Simon Yves,Yu‐Gui Peng,Andrea Alù
标识
DOI:10.1073/pnas.2427049122
摘要
In the last decade, the connection between physics and topology has resulted in the discovery of several new phenomena. A celebrated example is the field of topological insulators [X.-L. Qi, S.-C. Zhang, Rev. Mod. Phys. 83, 1057-1110 (2011)]., in which topological quantities describing the bulk medium response in reciprocal space dictate the presence of protected transport states at the boundary of a finite sample. Broken symmetries in the microscopic structure of a material play a prominent role in determining its topological features relevant to these phenomena. As another landmark phenomenon driven by broken symmetries, twistronics leverages the rotation angle between coupled layers to control in extreme ways the dispersion topology, leading to flat-band superconductivity [Y. Cao et al., Nature 556, 43-50 (2018)] and topological transitions for polaritons [G. Hu et al., Nature 582, 209-213 (2020)]. Here, we apply these concepts to elastodynamic waves, and exploit the twist degree-of-freedom to control broken symmetries in the microscopic structure of elastic metasurfaces, demonstrating extreme wave control. We predict and experimentally demonstrate topological transitions within twisted elastodynamic metasurfaces, which we harness for broadband, reconfigurable, and robust manipulation of phonons. Our twist-elastic approach opens alternative directions in microelectronics, microfluidics, and ultrasound sensing, leveraging precise multifunctional engineering of mechanical vibrations of relevance to many modern technologies.
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