Analytical design of acoustic metasurface cells incorporating meander-line and Helmholtz resonators (2504.08196v1)

Abstract: Gradient acoustic metasurfaces have shown strong potential for manipulation of acoustic waves across the audible and ultrasonic frequency ranges. The key challenge in designing acoustic metasurfaces is to create a series of sub-wavelength unit cells that match the desired phase response. The most commonly used geometry is a series of Helmholtz resonators, side-coupled to a narrow channel. Despite the existence of a closed-form solution for 3 side-coupled resonators, most reported designs instead make use of 4 or more resonators, which require opaque, optimization-based design approaches. We show that the limiting factor in designs based on side-coupled resonators is the requirement to use elements with a positive imaginary part of impedance, which implies a Helmholtz resonator operating above its fundamental resonance - contradicting the requirement for sub-wavelength volume. We show that by replacing some of the Helmholtz resonators with meander-line elements, the required impedance values can readily be realized within a sub-wavelength volume. The metasurface design approach is demonstrated for a lens operating at 3 kHz and verified numerically. Furthermore, incorporating meander-line elements leads to improved broadband focusing performance, even when no explicit dispersion engineering is included in the design. As this design includes narrow channels, we include the effects of thermo-viscous losses in our modeling, and confirm that our design still gives superior performance to the reference design using only Helmholtz resonators. Our design is expected to lead to more optimal performance of acoustic metasurface designs, and the ability to make use of a closed-form design formula is expected to facilitate the analysis of fundamental performance bounds and enable more explicit achromatic design processes.