1966
DOI: 10.1090/qam/99925
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Use of classical variational principles to determine bounds for the effective bulk modulus in heterogeneous media

Abstract: Abstract.Bounds are here derived for the effective bulk modulus in heterogeneous media, denoted by k*, using the two standard variational principles of elasticity. As trial functions for the stress and strain fields we use perturbation expansions that have been modified by the inclusion of a set of multiplicative constants. The first order perturbation effect is explicitly calculated and bounds for k* are derived in terms of the correlation functions (/(0)k'(i)lc'(s)) and ([fc'(r)A/(s)/|u(0)]) where n' and k' … Show more

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Cited by 219 publications
(81 citation statements)
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“…Note that for an isotropic material, L q = 3K q Λ h + 2G q Λ s , where K q and G q are the bulk and shear moduli of material phase q, and the hydrostatic and shear projection tensors are defined as Λ h = Using variational principles, third-order bounds of the effective bulk (K L ≤ K e ≤ K U ) and shear moduli (G L ≤ G e ≤ G U ) have been derived by Beran & Molyneux [26], McCoy [27], and were later simplified and improved upon by Milton [25], Milton & Phan-Thien [28] and Gibiansky & Torquato [51]. The bounds of the effective moduli considered in this work are given in Milton & Phan-Thien [28] as…”
Section: Ii) Elastic Constantsmentioning
confidence: 99%
See 1 more Smart Citation
“…Note that for an isotropic material, L q = 3K q Λ h + 2G q Λ s , where K q and G q are the bulk and shear moduli of material phase q, and the hydrostatic and shear projection tensors are defined as Λ h = Using variational principles, third-order bounds of the effective bulk (K L ≤ K e ≤ K U ) and shear moduli (G L ≤ G e ≤ G U ) have been derived by Beran & Molyneux [26], McCoy [27], and were later simplified and improved upon by Milton [25], Milton & Phan-Thien [28] and Gibiansky & Torquato [51]. The bounds of the effective moduli considered in this work are given in Milton & Phan-Thien [28] as…”
Section: Ii) Elastic Constantsmentioning
confidence: 99%
“…However, the sole microstructural information included in these bounds is the volume fractions (one-point probability functions) of the respective constituents. Three-point bounds for the effective permittivity were introduced by Beran [23], and these bounds were later simplified independently by Torquato [24] and Milton [25] as a function of the volume fraction c q and a microstructural parameter ζ q of each material phase q. Beran & Molneux [26], McCoy [27] and Milton & Phan-Thien [28] derived three-point bounds for the effective shear and bulk moduli incorporating c q , ζ q and an additional microstructural parameter η q . These microstructural parameters ζ q and η q depend on three-dimensional integrals involving one-, two-and three-point probability functions.…”
Section: Introductionmentioning
confidence: 99%
“…It is worth noting at this point that improved bounds, using more general polarizations leading to higher-order statistics, can also be derived [22][23][24]. However, it is often the case that such higher-order statistical correlation information for a given material is not known or difficult to determine accurately.…”
Section: Introductionmentioning
confidence: 99%
“…Their proposed bounds were later generalized by Walpole [65], Milton and Kohn [66] for anisotropic media, and by Zimmerman [67] to obtain bounds on the Poisson's ratio of the composites. Further improvements were achieved by using three point bounds in the works of Beran and Molyneux [68], Milton and Phan-Thien [69], and Torquato [70]. Employing the same approach, Rosen and Hashin [71]; Gibiansky and Torquato [72] derived bounds for the thermal expansion coefficient in thermoelastic problems and Bisegna and Luciano [73,74]; Hori and Nemat-Nasser [75] obtained bounds for the effective piezoelectric moduli in piezoelectric problems.…”
Section: Introductionmentioning
confidence: 99%