Acoustic radiation force and torque on nonspherical scatterers in the Born approximation

Proc. Meet. Acoust. Pub Date : 2018-10-08 DOI:10.1121/2.0000858

Thomas S. Jerome, Y. A. Ilinskii, E. A. Zabolotskaya, M. Hamilton

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Abstract

When the density and bulk modulus of a scatterer are similar to those of the surrounding liquid and the incident sound field is a standing wave, the Born approximation may be used to calculate the acoustic radiation force and torque acting on scatterers of arbitrary shape. The approximation consists of integration over the monopole and dipole contributions to the force acting on each differential volume element within the scatterer. The approach is applied to an axisymmetric scatterer, for which the force and torque may be expressed as an integral along the axis of symmetry. The integral is evaluated analytically for spherical and cylindrical scatterers. The accuracy of the Born approximation is assessed by comparison with the complete solutions for elastic spheres and prolate spheroids based on expansions of the incident and scattered fields in terms of spherical harmonics and spheroidal wave functions, respectively. Results are presented for various particle densities and bulk moduli relative to the surrounding liquid, as well as different shapes, sizes, and orientations of the particle with respect to the standing wave field.When the density and bulk modulus of a scatterer are similar to those of the surrounding liquid and the incident sound field is a standing wave, the Born approximation may be used to calculate the acoustic radiation force and torque acting on scatterers of arbitrary shape. The approximation consists of integration over the monopole and dipole contributions to the force acting on each differential volume element within the scatterer. The approach is applied to an axisymmetric scatterer, for which the force and torque may be expressed as an integral along the axis of symmetry. The integral is evaluated analytically for spherical and cylindrical scatterers. The accuracy of the Born approximation is assessed by comparison with the complete solutions for elastic spheres and prolate spheroids based on expansions of the incident and scattered fields in terms of spherical harmonics and spheroidal wave functions, re...

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玻恩近似下非球面散射体的声辐射力和转矩

当散射体的密度和体积模量与周围液体相似，入射声场为驻波时，玻恩近似可用于计算作用在任意形状散射体上的声辐射力和转矩。该近似包括对作用在散射体内每个微分体积元上的力的单极子和偶极子贡献的积分。该方法适用于轴对称散射体，其力和转矩可以表示为沿对称轴的积分。对球面散射体和圆柱散射体的积分进行了解析计算。通过与基于入射场和散射场分别用球谐波和球波函数展开的弹性球和长形球的完全解进行比较，评价了玻恩近似的准确性。结果表明，不同的粒子密度和体积模量相对于周围的液体，以及不同的形状，大小和方向的粒子相对于驻波场。当散射体的密度和体积模量与周围液体相似，入射声场为驻波时，玻恩近似可用于计算作用在任意形状散射体上的声辐射力和转矩。该近似包括对作用在散射体内每个微分体积元上的力的单极子和偶极子贡献的积分。该方法适用于轴对称散射体，其力和转矩可以表示为沿对称轴的积分。对球面散射体和圆柱散射体的积分进行了解析计算。通过与基于入射场和散射场的球面谐波和球面波函数展开的弹性球和延伸球的完全解进行比较，评价了玻恩近似的准确性。

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Proc. Meet. Acoust.

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