Uncovering and experimental realization of multimodal 3D topological metamaterials for low-frequency and multiband elastic wave control

Topological metamaterials unlock confined and robust elastic wave control in mechanical structures. Recent breakthroughs have precipitated the development of 3D topological mechanical metamaterials, which extend beyond the conventional 1D and 2D metamaterials to facilitate extraordinary wave manipulation along 2D planar and layer-dependent elastic waveguides. While promising, significant research gaps exist that impede the practical implementation of 3D topological metamaterials. The 3D topological metamaterials studied thus far are constrained to function in single frequency bandwidths that are typically in a high-frequency regime, and a comprehensive experimental investigation remains elusive. In this paper, we address these research gaps and advance the state of the art through the synthesis and experimental realization of a 3D topological metamaterial that exploits multimodal local resonance to enable low-frequency elastic wave control over multiple distinct frequency bands. The proposed metamaterial is geometrically configured to create multimodal local resonators whose frequency characteristics govern the emergence of four unique low-frequency topological states. Numerical simulations uncover how these topological states can be employed to achieve polarization-, frequency-, and layer-dependent wave manipulation in 3D structures. An experimental study results in the attainment of complete wave fields that unambiguously illustrate 2D topological waveguides and multi-polarized wave control in a physical testbed. The outcomes from this work open the door for future research with 3D topological mechanical metamaterials and reveal the applicability of the proposed metamaterial for various wave control applications.