Negative refraction of Lamb modes: A theoretical study

TL;DR

This paper presents a theoretical analysis of negative refraction of Lamb modes in elastic plates, demonstrating how mode conversion can be optimized for applications like cloaking and super-focusing.

Contribution

A semi-analytical model is developed to study negative refraction of Lamb modes, considering various parameters and confirming results with simulations and experiments.

Findings

Duralumin is optimal for broad frequency and angular conversion.

Step-like thickness and Poisson's ratio are key to optimizing negative refraction.

Theoretical predictions are validated by numerical and experimental results.

Abstract

This paper provides a theoretical investigation of negative refraction and focusing of elastic guided waves in a free-standing plate with a step-like thickness change. Under certain conditions, a positive phase velocity (forward) Lamb mode can be converted into a negative phase velocity (backward) mode at such interface, giving rise to negative refraction. A semi-analytical model is developed in order to study the influence of various parameters such as the material Poisson's coefficient, the step-like thickness, the frequency and the incidence angle. To this end, all the Lamb and shear horizontal propagating modes, but also a large number of their inhomogeneous and evanescent counterpart,s are taken into account. The boundary conditions applied to the stress-displacement fields at the thickness step yields an equation system. Its inversion provides the transmission and reflection coefficients between each mode at the interface. The step-like thickness and Poisson's ratio are shown to be key parameters to optimize the negative refraction process. In terms of material, Duralumin is found to be optimal as it leads to a nearly perfect conversion between forward and backward modes over broad frequency and angular ranges. An excellent focusing ability is thus predicted for a flat lens made of two symmetric thickness steps. Theoretical results are confirmed by a numerical FDTD simulation and experimental measurements made on an optimized Duralumin flat lens by means of laser interferometry. This theoretical study paves the way towards the optimization of elastic devices based on negative refraction, in particular for cloaking or super-focusing purposes.