Abstract
Intricate knowledge of dislocation networks in metals has proven paramount in understanding the constitutive behaviour of these materials but current experimental methods yield limited information on the characteristics of these networks. Recently, the isotropic anelastic response of metals has been used to investigate complex dislocation networks through the well-known phenomenon that the observed elastic constants are influenced by dislocations. Considering the dependence of the behaviour of a Frank-Read (FR) source on its initial dislocation character and using discerning characteristics of dislocations, i.e. Burgers vector, line sense and slip system, the present paper takes dislocation character, crystal structure and dislocation network geometry into account and obtains the anisotropic mechanical response for a generic Poisson’s ratio. In this work, the tensile test tangent moduli and yield points are presented for spatially uniform and nonuniform dislocation distributions across slip systems. First, the reversible shear strain of the FR source is derived as a function of initial dislocation character. The area swept by a mobile and initially straight dislocation segment pinned at both ends is given as an explicit function of the line stress. Secondly, the anisotropic anelastic strain contribution of FR sources to the total pre- and at-yield strain in single crystallites is calculated. For a given normal stress and superposition of the principal infinitesimal linear elastic lattice strain and anelastic dislocation strain, the tangent moduli are presented. The moduli and the inception of plastic flow have a notable dependence on initial dislocation character, spatial dislocation distribution and loading direction.
Highlights
It is well-known that the mechanical deformation of metals is governed by the generation, glide and storage of dislocations
The anisotropic anelastic strain contribution of FR sources to the total pre- and at-yield strain in single crystallites is calculated
We present an analytical model of the anisotropic tangent moduli and the yield points for nonuniform dislocation networks in single crystallites
Summary
It is well-known that the mechanical deformation of metals is governed by the generation, glide and storage of dislocations. DeWit and Koehler [26] obtained a parametric function for the static equilibrium shape of the FR source as a function of the self-energy by calculus of variations Following their seminal work [26], Kovacs [27] formulated a physical yield criterion depending on the initial dislocation character of the FR source. Cash and Cai [14] investigated the dislocation contribution to acoustic non-linearity in order to non-destructively monitor plastic deformation They presented an implicit analytical expression for the anelastic dislocation shear strain contribution of initially straight edge and screw segments. We present an analytical model of the anisotropic tangent moduli and the yield points for nonuniform dislocation networks in single crystallites. Constitutive model takes account of anisotropic effects on a per-grain basis and presents a significant step towards modelling of crystallographically textured cubic materials
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