Ultra-thin normal-shear-coupled metabarrier for low-frequency underwater sound insulation (2506.09248v1)

Abstract: Underwater noise pollution caused by anthropogenic activities, such as offshore wind farms, significantly affects marine life, hindering the intra- and inter-specific interactions of many aquatic species. A common strategy to mitigate these effects is to enclose the noise source within a physical barrier to achieve acceptable noise levels in the surrounding region. Underwater barriers typically achieve noise reduction through sound absorption based on locally resonant systems (e.g., foam and bubble elements) or sound reflecting systems (e.g., air bubble curtains). Although locally resonant-based solutions can yield significant noise attenuation levels, their performance is usually narrow-band. On the other hand, sound-reflecting systems require wider dimensions, presenting poor performance in the low-frequency range. Thus, significant low-frequency underwater noise attenuation remains an open issue, especially when considering thin structures that perform over a broad frequency range. In this work, we present the design of thin metamaterial-based acoustic barriers whose underwater noise attenuation is owed to tailored anisotropic material properties. A topology optimization approach is used to obtain a unit cell that maximizes the coupling between normal stresses and shear strains (and vice-versa). The resulting metabarrier presents a sub-wavelength thickness-to-wavelength ratio in the low-frequency range (circa 1/70 below 1 kHz) and also high sound transmission loss values at higher frequencies (almost 100 dB above 2 kHz). We also investigate the effects of increased hydrostatic pressure, presenting structural modifications that enable real-world applications. The results presented in this work indicate an efficient metamaterial-based solution for the mitigation of underwater noise, suggesting a fruitful direction for the exploitation of anisotropy in acoustic insulation applications.