2014
DOI: 10.1088/0266-5611/30/12/125008
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Exact determination of the volume of an inclusion in a body having constant shear modulus

Abstract: Abstract. We derive an exact formula for the volume fraction of an inclusion in a body when the inclusion and the body are linearly elastic materials with the same shear modulus. Our formula depends on an appropriate measurement of the displacement and traction around the boundary of the body. In particular, the boundary conditions around the boundary of the body must be such that they mimic the body being placed in an infinite medium with an appropriate displacement applied at infinity.

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Cited by 4 publications
(6 citation statements)
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“…This section generalizes the ideas developed in [49], where it was shown how Hill's exact relation in the theory of composites, could be used to derive exact identities satisfied by the "Dirichlet-to-Neumann map" of a body Ω containing two elastically isotropic materials with the same shear modulus: in particular, these identities allow one to exactly deduce the volume fractions occupied by the phases from boundary measurements. The key idea was to apply (non-local) boundary conditions on the boundary tractions and displacements on the boundary ∂Ω of Ω in such a way that they mimic the body placed in an appropriate infinite medium with appropriate sources outside.…”
Section: Links Between Green's Functions Of Different Physical Problemsmentioning
confidence: 79%
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“…This section generalizes the ideas developed in [49], where it was shown how Hill's exact relation in the theory of composites, could be used to derive exact identities satisfied by the "Dirichlet-to-Neumann map" of a body Ω containing two elastically isotropic materials with the same shear modulus: in particular, these identities allow one to exactly deduce the volume fractions occupied by the phases from boundary measurements. The key idea was to apply (non-local) boundary conditions on the boundary tractions and displacements on the boundary ∂Ω of Ω in such a way that they mimic the body placed in an appropriate infinite medium with appropriate sources outside.…”
Section: Links Between Green's Functions Of Different Physical Problemsmentioning
confidence: 79%
“…Depending on the nature of the exact relations, boundary field equalities may involve the volume fraction of one phase in a body containing two phases. and thus allow the volume fraction to be exactly determined (e.g., see [49]).…”
Section: Links Between Green's Functions Of Different Physical Problemsmentioning
confidence: 99%
See 1 more Smart Citation
“…Shear modulus (G) is a physical quantity that describes a material's resistance to shear deformation. It measures the material's tendency to deform under shear stress [15] . The shear modulus of Al2O3 differs significantly from that of the steel matrix, potentially leading to different shear strains between inclusions and the matrix under stress.…”
Section: Crystallographic Parametersmentioning
confidence: 99%
“…Regularized inversion schemes and stable reconstruction algorithms to recover µ and its moments from data on the effective complex permittivity were developed in Cherkaev (2001Cherkaev ( , 2004; Cherkaev and Ou (2008); Bonifasi-Lista and Cherkaev ( 2009 Other approaches to the volume fraction bounds include Engström (2005); Milton (2012); Thaler and Milton (2014) based on estimates for higher order moments and on variational bounds, as well as direct inversion of known formulas or mixing rules Bergman and Stroud (1992); Levy and Cherkaev (2013) for effective properties of composites with specific structure, however, an advantage of the methods discussed here, is their applicability without a priori assumption about the microgeometry.…”
Section: Spectral Measure Computations For Uniaxial Polycrystalline M...mentioning
confidence: 99%