Graded arrays of vertical barriers: rainbow reflection and broadband energy absorption

TL;DR

This paper explores the use of graded arrays of vertical barriers to achieve broadband wave energy absorption through rainbow reflection, combining theoretical analysis and optimization to design near-perfect absorbers for water waves.

Contribution

It introduces a novel approach to broadband wave energy absorption using graded barriers and floating bodies, demonstrating near-perfect absorption over multiple frequencies.

Findings

Rainbow reflection causes wave energy amplification at different locations.

Wave slowing down explains the broadband reflection effect.

Optimized rainbow absorbers achieve near-perfect energy absorption.

Abstract

The rainbow reflection effect describes the broadband spatial separation of wave spectral components caused by a spatially graded array of resonators. Although mainly studied in optics and acoustics, this phenomenon has recently been demonstrated both theoretically and experimentally for water waves travelling through an array of vertical cylinders. Linear water wave scattering by a array of vertical, surface-piercing barriers is considered here, in which both the submergence and spacing between the barriers are spatially graded. The rainbow reflection effect arises naturally as wave energy temporarily becomes amplified at different locations depending on frequency. Band diagram calculations are used to demonstrate that this is a consequence of the wave gradually slowing down throughout the array. The wave/barriers scattering problem is then augmented by positioning heave-restricted, rectangular floating bodies equipped with a linear damping mechanism between each adjacent pair of barrier. A solution to the resulting boundary-value problem is obtained using an integral equation/Galerkin method. Using constrained optimisation, passive rainbow absorbers are designed that achieve near-perfect absorption over (i) a discrete set of frequencies, and (ii) over an octave. This suggests potential applications of rainbow absorbers in the design of smart coastal technologies.