Hyperbolic Space Spectral Characteristics in a Network of Mechanical Linkages

TL;DR

This paper explores hyperbolic space-based mechanical lattices, revealing boundary-localized vibrational modes that could enable advanced wave control and protection of bulk media from boundary perturbations.

Contribution

It introduces a novel mechanical lattice design based on hyperbolic geometry, demonstrating boundary-dominated spectral properties and wave propagation behaviors through numerical and experimental methods.

Findings

High density of localized boundary modes in hyperbolic lattices

Boundary-driven wave propagation confirmed experimentally

Lattice exhibits boundary-dominated vibrational spectrum

Abstract

We investigate the dynamic properties of elastic lattices defined by tessellations of a curved hyperbolic space. The lattices are obtained by projecting nodes of a regular hyperbolic tessellation onto a flat disk and then connecting those sites with simple linkages. Numerical and experimental investigations illustrate how their vibrational spectral properties are characterized by a high density of modes that are localized at the domain boundaries. Such properties govern the propagation of waves induced by broadband inputs. This suggests the potential for applications seeking the protection of bulk media from boundary-incident perturbations. We uncover the boundary-dominated nature of an exemplary hyperbolic lattice through the evaluation and analysis of its integrated density of states and vibrational spectrum. The dynamics of the lattice are also contextualized by comparing them with those of continuous disks characterized by Euclidean and hyperbolic property distributions, which confirms that the lattice retains the boundary-dominated spectrum observed in the hyperbolic plane. We then numerically investigate the response of the lattice to transient pulses incident on the boundary and find that edge-confined wave propagation occurs. The modal and transient pulse propagation behavior of the lattice is experimentally validated in a milled aluminum sample. By leveraging hyperbolic geometry, our mechanical lattice ushers in a novel class of mechanical metamaterials with boundary-dominated wave phenomena reminiscent of topologically protected systems suitable for applications in advanced wave control.