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Geometrically nonlinear shape-memory polycrystals made from a two-variant material

Robert V. Kohn, Barbara Niethammer (2010)

ESAIM: Mathematical Modelling and Numerical Analysis

Bhattacharya and Kohn have used small-strain (geometrically linear) elasticity to analyze the recoverable strains of shape-memory polycrystals. The adequacy of small-strain theory is open to question, however, since some shape-memory materials recover as much as 10 percent strain. This paper provides the first progress toward an analogous geometrically nonlinear theory. We consider a model problem, involving polycrystals made from a two-variant elastic material in two space dimensions. The linear theory...

Global-Local subadditive ergodic theorems and application to homogenization in elasticity

Christian Licht, Gérard Michaille (2002)

Annales mathématiques Blaise Pascal

Gradient theory for plasticity via homogenization of discrete dislocations

Adriana Garroni, Giovanni Leoni, Marcello Ponsiglione (2010)

Journal of the European Mathematical Society

We deduce a macroscopic strain gradient theory for plasticity from a model of discrete dislocations. We restrict our analysis to the case of a cylindrical symmetry for the crystal under study, so that the mathematical formulation will involve a two-dimensional variational problem. The dislocations are introduced as point topological defects of the strain fields, for which we compute the elastic energy stored outside the so-called core region. We show that the $Γ$ -limit of this energy (suitably rescaled),...

Displaying 1 – 3 of 3

Geometrically nonlinear shape-memory polycrystals made from a two-variant material

Global-Local subadditive ergodic theorems and application to homogenization in elasticity

Gradient theory for plasticity via homogenization of discrete dislocations

Currently displaying 1 – 3 of 3