A hyperbolic framework for shear sound beams in nonlinear solids

Michel Destrade

doi:http://hdl.handle.net/10379/18079

A hyperbolic framework for shear sound beams in nonlinear solids

Michel Destrade

Mathematics

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Abstract

In soft elastic solids, directional shear waves are in general governed by coupled nonlinear KZK-type equations for the two transverse velocity components, when both quadratic nonlinearity and cubic nonlinearity are taken into account. Here we consider spatially two-dimensional wave fields. We propose a change of variables to transform the equations into a quasi-linear first-order system of partial differential equations. Its numerical resolution is then tackled by using a path-conservative MUSCL-Osher finite volume scheme, which is well-suited to the computation of shock waves. We validate the method against analytical solutions (Greens function, plane waves). The results highlight the generation of odd harmonics and of second-order harmonics in a Gaussian shear-wave beam.

Original language	English (Ireland)
Journal	Communications In Nonlinear Science And Numerical Simulation
Volume	103
DOIs	https://doi.org/http://hdl.handle.net/10379/18079
Publication status	Published - 1 Dec 2021

Authors (Note for portal: view the doc link for the full list of authors)

Authors
Berjamin, H; Destrade, M

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http://hdl.handle.net/10379/18079

Cite this

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title = "A hyperbolic framework for shear sound beams in nonlinear solids",

abstract = "In soft elastic solids, directional shear waves are in general governed by coupled nonlinear KZK-type equations for the two transverse velocity components, when both quadratic nonlinearity and cubic nonlinearity are taken into account. Here we consider spatially two-dimensional wave fields. We propose a change of variables to transform the equations into a quasi-linear first-order system of partial differential equations. Its numerical resolution is then tackled by using a path-conservative MUSCL-Osher finite volume scheme, which is well-suited to the computation of shock waves. We validate the method against analytical solutions (Greens function, plane waves). The results highlight the generation of odd harmonics and of second-order harmonics in a Gaussian shear-wave beam.",

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year = "2021",

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language = "English (Ireland)",

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T1 - A hyperbolic framework for shear sound beams in nonlinear solids

AU - Destrade, Michel

PY - 2021/12/1

Y1 - 2021/12/1

N2 - In soft elastic solids, directional shear waves are in general governed by coupled nonlinear KZK-type equations for the two transverse velocity components, when both quadratic nonlinearity and cubic nonlinearity are taken into account. Here we consider spatially two-dimensional wave fields. We propose a change of variables to transform the equations into a quasi-linear first-order system of partial differential equations. Its numerical resolution is then tackled by using a path-conservative MUSCL-Osher finite volume scheme, which is well-suited to the computation of shock waves. We validate the method against analytical solutions (Greens function, plane waves). The results highlight the generation of odd harmonics and of second-order harmonics in a Gaussian shear-wave beam.

AB - In soft elastic solids, directional shear waves are in general governed by coupled nonlinear KZK-type equations for the two transverse velocity components, when both quadratic nonlinearity and cubic nonlinearity are taken into account. Here we consider spatially two-dimensional wave fields. We propose a change of variables to transform the equations into a quasi-linear first-order system of partial differential equations. Its numerical resolution is then tackled by using a path-conservative MUSCL-Osher finite volume scheme, which is well-suited to the computation of shock waves. We validate the method against analytical solutions (Greens function, plane waves). The results highlight the generation of odd harmonics and of second-order harmonics in a Gaussian shear-wave beam.

U2 - http://hdl.handle.net/10379/18079

DO - http://hdl.handle.net/10379/18079

M3 - Article

VL - 103

JO - Communications In Nonlinear Science And Numerical Simulation

JF - Communications In Nonlinear Science And Numerical Simulation

ER -

A hyperbolic framework for shear sound beams in nonlinear solids

Abstract

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