Superscattering of water waves
– breaking the single channel scattering limit.
Recently, the National Science Review published the study of Huaping Wang’s group at Zhejiang University online. Inspired by electromagnetic metamaterials, the research team designed and fabricated a water wave superscattering device based on degeneracy resonance by using the similarity of water wave equation and electromagnetic wave equation under shallow water conditions, which was realized it experimentally.
Water waves are a very intuitive fluctuating phenomenon that is widely observed in the natural world. Understanding and controlling the propagation of water waves is significant for both hydrodynamics and marine engineering. In recent years, metamaterials have developed rapidly and become a beneficial tool to manipulate electromagnetic waves, elastic waves, acoustic waves and water waves. Enhanced water wave scattering using metamaterials has a wide range of promising applications in marine energy harvesting and coastal protection.
Inspired by the superscattering in electromagnetic and acoustic waves, it is possible to design water wave superscatterers based on transformation optics to achieve an increase in the scattering intensity of a given object. However, its experimental implementation remains a great challenge due to the extreme requirements on anisotropic parameters and in water wave conditions.
Based on the degenerate resonant superscattering mechanism, the researchers theoretically designed and experimentally verified the superscatterer structure of water waves in an experimental water tank. The subwavelength superscatterer is composed of multiple concentric cylinders with different heights, and the geometry and operating frequency of the superscatterer are optimized by a simulated annealing algorithm. By designing resonances with different angular momentum channels, the total scattering cross section can break the limit of single-channel scattering by several times and also far exceed the scattering intensity of ordinary scatterers of the same size. For an ordinary scatterer, the resonances are spread out and the total scattering cross section is limited by the single channel.
In the experiments, the research group measured the near-field patterns of the water-wave superscatterers, which were in agreement with the theoretical predictions and numerical simulations, and further measured the superscattering effects under different boundary conditions, water depths, and frequencies.
This study provides a simple and low-cost method to enhance the scattering of water waves, which can be used to enhance the scattering of small sub-wavelength objects, and this is highly relevant for marine engineering, offshore coastal protection, etc., and may be used in marine energy harvesting devices and coastal protection facilities in the future.
See the article:
Superscattering of water waves
National Science Review
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