Labyrinthine acoustic metamaterials with space-coiling channels for low-frequency sound control

TL;DR

This study numerically investigates labyrinthine acoustic metamaterials with space-coiling channels, revealing their ability to achieve broadband total sound reflection at low frequencies through wave dynamics analysis.

Contribution

It provides a direct modeling approach of wave propagation in folded channels, highlighting differences from straight slits and demonstrating broadband reflection capabilities.

Findings

Channels allow wave propagation opposite to incident waves, affecting dynamics.

Total wave reflection occurs at band gap frequencies, unaffected by air dissipation.

Tuning channel width controls absorption and reflection properties.

Abstract

We numerically analyze the performance of labyrinthine acoustic metamaterials with internal channels folded along a Wunderlich space-filling curve to control low-frequency sound in air. In contrast to previous studies, we perform direct modeling of wave propagation through folded channels, not introducing effective theory assumptions. As a result, we reveal that metastructures with channels, which allow wave propagation in the opposite direction to incident waves, have different dynamics as compared to those for straight slits of equivalent length. The differences are attributed to activated tortuosity effects and result in 100% wave reflection at band gap frequencies. This total reflection phenomenon is found to be insensitive to thermo-viscous dissipation in air. For labyrinthine channels generated by iteration levels, one can achieve broadband total sound reflection by using a metamaterial monolayer and efficiently control the amount of absorbed wave energy by tuning the channel width. Thus, the work contributes to a better understanding of labyrinthine metamaterials with potential applications for reflection and filtering of low-frequency airborne sound.