@Article{cmes.2014.097.001,
AUTHOR = {Z. D.  Han, S. N.  Atluri},
TITLE = {Eshelby Stress Tensor T: a Variety of Conservation Laws for T in Finite Deformation Anisotropic Hyperelastic Solid \& Defect Mechanics, and the MLPG-Eshelby Method in Computational Finite Deformation Solid Mechanics-Part I},
JOURNAL = {Computer Modeling in Engineering \& Sciences},
VOLUME = {97},
YEAR = {2014},
NUMBER = {1},
PAGES = {1--34},
URL = {http://www.techscience.com/CMES/v97n1/27126},
ISSN = {1526-1506},
ABSTRACT = {The concept of a stress tensor [for instance, the Cauchy stress <b>σ</b>, Cauchy (1789-1857); the first Piola-Kirchhoff stress <b>P</b>, Piola (1794-1850), and Kirchhoff (1824-1889); and the second Piola-Kirchhoff stress, <b>S</b>] plays a central role in Newtonian continuum mechanics, through a physical approach based on the conservation laws for linear and angular momenta. The pioneering work of Noether (1882-1935), and the extraordinarily seminal work of Eshelby (1916- 1981), lead to the concept of an “energy-momentum tensor” [Eshelby (1951)]. An alternate form of the “energy-momentum tensor” was also given by Eshelby (1975) by taking the two-point deformation gradient tensor as an independent field variable; and this leads to a stress measure <b>T</b> (which may be named as the Eshelby Stress Tensor). The corresponding conservation laws for <b>T</b> in terms of the pathindependent integrals, given by Eshelby (1975), were obtained through a sequence of imagined operations to “cut the stress states” in the current configuration. These imagined operations can not conceptually be extended to nonlinear steady state or transient dynamic problems [Eshelby (1975)]. To the authors’ knowledge, these path-independent integrals for dynamic finite-deformations of inhomogeneous materials were first derived by Atluri (1982) by examining the various internal and external work quantities during finite elasto-visco-plastic dynamic deformations, to derive the energy conservation laws, in the undeformed configuration [ref. to Eq. (18) in Atluri (1982)]. The stress tensor <b>T</b> was derived, independently, in its path-independent integral form for computational purposes [ref. to Eq. (30) in Atluri (1982)]. The corresponding integrals were successfully applied to nonlinear dynamic fracture analysis to determine “the energy change rate”, denoted as <b>T*</b>. A similar analytical work for elasto-statics was reported by Hill (1986). With the use of the stress measure <b>T</b> for finite-deformation solid and defect mechanics, the concept of “the strength of the singularities”, labeled in this paper as the vector <b>T*</b>, is formulated for a defective hyperelastic anisotropic solid undergoing finite deformations, in its various path-independent integral forms.<br/>
We first derive a vector balance law for the Eshelby stress tensor <b>T</b>, and show that it involves a mathematically “weak-form” of a vector momentum balance law for <b>P</b>. In small deformation linear elasticity (where <b>P, S</b> and <b>σ</b> are all equivalent), the stress tensor <b>σ</b> is linear in the deformation gradient <b>F</b>. Even in small deformation linear elasticity, the Eshelby Stress Tensor <b>T</b> is quadratic in <b>F</b>. By considering the various weak-forms of the balance law for <b>T</b> itself, we derive a variety of “conservation laws” for <b>T</b> in Section 2. We derive four important “path-independent” integrals, <i>T<sub>K</sub><sup style="margin-left:-5px">∗</sup></i>, <i>T<sub>L</sub><sup style="margin-left:-5px">∗(L)</sup></i> , <i>T<sup>∗(M)</sup></i>, <i>T<sub>IJ</sub><sup style="margin-left:-5px">∗(G)</sup></i> , in addition to many others. We show the relation of <i>T<sub>K</sub><sup style="margin-left:-5px">∗</sup></i>, <i>T<sub>L</sub><sup style="margin-left:-5px">∗(L)</sup></i> , <i>T<sup>∗(M)</sup></i> integrals to the <i>J-, L-</i> and <i>M-</i> integrals given in Knowles and Sternberg (1972). The four laws derived in this paper are, however, valid for finite-deformation anisotropic hyperelastic solid- and defect-mechanics. Some discussions related to the use of <b>T</b> in general computational solid mechanics of finitely deformed solids are given in Section 3. The application of the Eshelby stress tensor in computing the deformation of a one-dimensional bar is formulated in Section 4 for illustration purposes. We present two computational approaches: the Primal Meshless Local Petrov Galerkin (MLPG)-Eshelby Method, and the Mixed MLPG-Eshelby Method, as applications of the original MLPG method proposed by Atluri (1998,2004). More general applications of <b>T</b> directly, in computational solid mechanics of finitely deformed solids, will be reported in our forthcoming papers, for mechanical problems, in their explicitly-linearized forms, through the Primal MLPG-Eshelby and the Mixed MLPG-Eshelby Methods.},
DOI = {10.3970/cmes.2014.097.001}
}