Investigation of acoustoelastic surface acoustic waves in prestressed media

Dispersion of broadband surface acoustic waves (SAWs) is often used for the nondestructive evaluation of near-surface elastic properties of materials. The accurate forward model of SAW propagation is essential for inversion. In this paper, we present a combining semi-analytical finite element (SAFE) and perfectly matched layer method for accurately predicting the phase velocity dispersion, attenuation and polarization modes of SAWs in any prestressed anisotropic layered half-space. Equations of motion are formulated based on the Biot's theory of small deformations influenced by initial stress, so it does not matter whether the residual stress results from hyperelastic transformations. The simulated results are firstly validated by the solutions from the exact three-dimensional elasticity theory-based method. The SAFE method is then used to discuss the effect of material anisotropy and residual stress on the SAWs. Finally, the method is applied to two practical examples. The differences and similarities of two common types of acoustoelastic theories are also discussed.

Automated summary

This paper presents a combined semi-analytical finite element (SAFE) and perfectly matched layer method for accurately predicting the dispersion, attenuation, and polarization modes of surface acoustic waves (SAWs) in materials. The method is validated by comparing the simulated results with exact three-dimensional elasticity theory-based solutions, and the effects of material anisotropy and residual stress on SAWs are discussed. The method is also applied to practical examples and the differences and similarities of two common acoustoelastic theories are discussed.