Dimensional hierarchy of topological bound states in the continuum
Shunda Yin, Zhenyu Wang, Liping Ye, Hailong He, Manzhu Ke, Weiyin Deng, Jiuyang Lu, Zhengyou Liu

TL;DR
This paper reports the experimental discovery of a hierarchical coexistence of 2D surface and 1D hinge topological bound states in a 3D phononic crystal, enabling robust wave manipulation across dimensions.
Contribution
It introduces a novel multidimensional hierarchy of topological bound states in a single system, leveraging separability and valley Chern numbers for robustness.
Findings
Coexistence of 2D and 1D topological bound states in a single system
Propagation of TBICs is robust against defects and leakage
Potential for designing advanced acoustic devices
Abstract
Bound states in the continuum (BICs), with the ability of trapping and manipulating waves within the radiation continuum, have gained significant attention for their potential applications in optics and acoustics. However, challenges arise in reducing wave leakage and noise from fabrication imperfections. The emergence of robust wave manipulations based on topological BICs (TBICs) offers promising solutions. Traditionally, TBICs of different dimensions are observed separately in distinct systems. Here, we report the experimental discovery of the coexistence of two-dimensional surface TBICs and one-dimensional hinge TBICs in a single three-dimensional phononic crystal system. Such an unprecedented dimensional hierarchy of TBICs is triggered by the mechanism of separability and protected by the valley Chern numbers. Notably, these TBICs inherit dispersive propagation characteristics from…
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