Elastic fields of inclusions in anisotropic media

Kinoshita, N.; Mura, T.

doi:10.1002/pssa.2210050332

Cited by 266 publications

(104 citation statements)

References 7 publications

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“…The orientation and eccentricity of such an optimal ellipse is uniquely defined by the value of the average strain (Barnett et al, 1974;Kaganova and Roitburd, 1987;Kardonski and Roitburd, 1972;Kinoshita and Mura, 1971;Lee, Barnett and Aaronson, 1977;Pineau, 1976). The above calculation recovers those parameters precisely, by realizing the optimal ellipse as a limit of microstructures that are optimal for any volume fraction.…”

Section: Now Let's Study What Happens To the Shape Of The Inclusions mentioning

confidence: 76%

Microstructures minimizing the energy of a two phase elastic composite in two space dimensions. II: The vigdergauz microstructure

Grabovsky

Kohn

1995

Journal of the Mechanics and Physics of Solids

123

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For modeling coherent phase transformations, and for applications to structural optimization, it is of interest to identify microstructures with minimal energy or maximal stiffness. S. Vigdergauz has shown the existence of a particularly simple microstructure with extremal elastic behavior, in the context of two-phase composites made from * This work was done while Y. G. was a student at the Courant Institute. † The work of R. V. K. was partially supported by ARO contract DAAL 03-92-G-0011 and NSF grants DMS-9404376 and DMS-9402763. 1 isotropic components in two space dimensions. This "Vigdergauz microstructure" consists of a periodic array of appropriately shaped inclusions. We provide an alternative discussion of this microstructure and its properties. Our treatment includes an explicit formula for the shape of the inclusion, and an analysis of various limits. We also discuss the significance of this microstructure (i) for minimizing the maximum stress in a composite, and (ii) as a large volume fraction analog of Michell trusses in the theory of structural optimization.

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Section: Now Let's Study What Happens To the Shape Of The Inclusions mentioning

confidence: 76%

Microstructures minimizing the energy of a two phase elastic composite in two space dimensions. II: The vigdergauz microstructure

Grabovsky

Kohn

1995

Journal of the Mechanics and Physics of Solids

123

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“…5(a)], which suggests that the projected thickness is less along the defects. It has been known 23) that the shape and orientation of coherent precipitates in cubic metals and alloys are determined by the elastic anisotropy of the matrix: when the internal pressure is hydrostatic and the inequality C 0 ð¼ ðC 11 À C 12 Þ=2Þ < C 44 holds between the elastic constants of the matrix, the precipitate shape that is elastically most stable is the disc on the {001} plane. On the other hand, if C 0 > C 44 , the most stable shape is needle-like extending along the h111i direction.…”

Section: Methodsmentioning

confidence: 99%

Substructures of Gas-Ion-Irradiation-Induced Surface Blisters in Silicon Studied by Cross-Sectional Transmission Electron Microscopy

Muto

Enomoto

2005

Mater. Trans.

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Internal structures of surface blisters and their precursors in Si formed by H þ , D þ and He þ irradiation were examined by cross-sectional transmission electron microscopy (XTEM). The skin structures of H þ -D þ -and He þ -blisters reflected the difference in the damage accumulation, and chemical interaction between the implant ion and silicon. These differences had a direct influence on the defect structures of the damaged layer, which played essential roles in the blistering mechanisms. It was found that blister skin thickness derived by grazing incidence electron microscopy (GIEM) and electron energy-loss spectroscopy (EELS) was underestimated compared to direct measurement by XTEM. The origin of this discrepancy is discussed.

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“…Total strain is given by a summation of all strains including elastic strain, thermal strain, strain, eij, satisfies Hooke's law. Eigenstrain, a general name given by KINOSHITA and MURA (1971) for the stress-free strain in ESHELBY (1957), includes strains that are not related uniquely to stress, e.g., initial strains, plastic strains, strains due to phase transformations or thermal expansion, etc. (MURA and CHENG, 1977;MURA and MORI, 1976).…”

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confidence: 99%

Seismic velocity anisotropy in a medium cotaining oriented cracks. Transversely isotropic case.

1982

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A new method was developed for calculating effective elastic parameters of a medium containing oblate spheroidal cracks having parallel planes. This new method is free from the restrictions of isotropic matrix material and low crack density. Velocity anisotropy was calculated for the case of oriented cracks filled with fluid. Effects of crack aspect ratio, fluid bulk modulus, and crack volume on velocity anisotropy were investigated. The present results showed smaller anisotropy than that given by ANDERSON et al. (1974) for a medium containing oriented spheroidal cracks. The relation between velocity and crack density parameter (ratio of porosity to aspect ratio of cracks divided

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Elastic fields of inclusions in anisotropic media

Cited by 266 publications

References 7 publications

Microstructures minimizing the energy of a two phase elastic composite in two space dimensions. II: The vigdergauz microstructure

Microstructures minimizing the energy of a two phase elastic composite in two space dimensions. II: The vigdergauz microstructure

Substructures of Gas-Ion-Irradiation-Induced Surface Blisters in Silicon Studied by Cross-Sectional Transmission Electron Microscopy

Seismic velocity anisotropy in a medium cotaining oriented cracks. Transversely isotropic case.

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