Anomalous wavefront control via nonlinear acoustic metasurface through second-harmonic tailoring and demultiplexing

TL;DR

This paper introduces a nonlinear acoustic metasurface that leverages second-harmonic generation to control wavefronts, enabling functionalities like wave steering and focusing through nonlinear effects.

Contribution

It presents a novel nonlinear acoustic metasurface design that demultiplexes frequency components and achieves advanced wavefront control via second-harmonic tailoring.

Findings

Effective second-harmonic generation demonstrated

Able to steer, focus, and bend acoustic waves

Separates harmonic components for individual control

Abstract

We propose a nonlinear acoustic metasurface concept by exploiting the nonlinearity of the locally resonant unit cells formed by curved beams. The analytical model is established to explore the nonlinear phenomenon, specifically the second-harmonic generation (SHG) of the acoustic waveguide and validated through numerical and experimental studies. Novel nonlinear acoustic metasurfaces are developed to demultiplex different frequency components and achieve anomalous wavefront control of SHG in the transmitted region. To this end, we demonstrate wave steering, wave focusing, and self-bending propagation. Our results show that the proposed nonlinear metasurface provides an effective and efficient platform to achieve significant SHG, and separate different harmonic components for wavefront control of individual harmonics. Overall, this study offers new avenues to harness nonlinear effects for acoustic wavefront tailoring and develops new potential toward advanced technologies to manipulate acoustic waves.