Sound diffusion with spatiotemporally modulated acoustic metasurfaces

TL;DR

This paper introduces a novel spatiotemporal modulation technique for acoustic metasurfaces to enhance sound diffusion, overcoming limitations of traditional diffusers by scattering sound into multiple frequency-wavenumber pairs.

Contribution

The study develops a semi-analytical model for spatiotemporally modulated acoustic metasurfaces, demonstrating improved diffusion performance over conventional diffusers.

Findings

Significant enhancement in sound diffusion due to spatiotemporal modulation.

Scattering into additional frequency-wavenumber pairs and diffraction orders.

Model verification with finite element simulations confirms effectiveness.

Abstract

Traditional sound diffusers are quasi-random phase gratings attached to reflecting surfaces whose purpose is to augment the spatiotemporal incoherence of the acoustic field scattered from reflective surfaces. This configuration allows one to cover a large reflecting surface by periodically tiling the diffuser unit cells to cover a large area while reducing undesirable specular reflection for incident plane waves. However, the periodic arrangement of the unit cells leads to coherent constructive and destructive interference in the scattered field in some directions which is undesirable for achieving acoustic diffusivity. The spatial uniformity of acoustic energy scattered from conventional diffusers constructed in this way is a fundamental limitation of the traditional approach which is not easily overcome when one wishes to cover large reflecting surfaces. In this work, we investigate spatiotemporal modulation of the surface acoustic admittance of an acoustic diffuser as a new approach to improve the sound diffusion. We develop a semi-analytical model that employs Fourier series expansion to determine the scattered sound field from a surface admittance consisting of a quadratic residue diffuser (QRD) design whose individual well admittances are modulated with a traveling wave with modulation frequency, $\omega_{\mrm{m}}$, amplitude, $Y_\mrm{m}$, and a wavenumber that matches the unit cell length, $\Lambda$. We observe significant improvement in diffusion performance due to the fact that the spatiotemporal modulation scatters sound into additional frequency--wavenumber pairs associated with harmonics of the modulation frequency and their diffraction orders. The semi-analytical model results are verified using time-domain finite element model.