Zero refractive index in space-time acoustic metamaterials

TL;DR

This paper introduces a novel space-time acoustic metamaterial that achieves zero refractive index by breaking time-reversal symmetry and using space-time modulation, enabling advanced wave control with reconfigurable properties.

Contribution

It presents a new approach to realize zero refractive index in acoustic metamaterials through space-time modulation and time-Floquet analysis, differing from previous methods based on accidental degeneracy.

Findings

Demonstrated zero refractive index in a time-Floquet acoustic metamaterial.

Confirmed behavior through full-wave finite element simulations.

Established space-time metamaterials as a reconfigurable wave control platform.

Abstract

New scientific investigations of artificially structured materials and experiments have exhibit wave manipulation to the extreme. In particular, zero refractive index metamaterials have been on the front line of wave physics research for their unique wave manipulation properties and application potentials. Remarkably, in such exotic materials, time-harmonic fields have infinite wavelength and do not exhibit any spatial variations in their phase distribution. This unique feature can be achieved by forcing a Dirac cone to the center of the Brillouin zone ( point), as previously predicted and experimentally demonstrated in time-invariant metamaterials by means of accidental degeneracy between three different modes. In this article, we propose a different approach that enables true conical dispersion at with twofold degeneracy, and generates zero index properties. We break time-reversal symmetry and exploit a space-time modulation scheme to demonstrate a time-Floquet acoustic metamaterial with zero refractive index. This behavior, predicted using stroboscopic analysis, is confirmed by fullwave finite elements simulations. Our results establish the relevance of space-time metamaterials as a novel reconfigurable platform for wave control.