Hypo-elasticity, Cauchy-elasticity, corotational stability and monotonicity in the logarithmic strain

Abstract

We combine the rate-formulation for the objective, corotational Zaremba-Jaumann rate align D ZJ D t [σ] = H ZJ(σ).D, D = sym D v\,, align operating on the Cauchy stress σ, the Eulerian strain rate D and the spatial velocity v with the novel corotational stability postulate (CSP)equation D ZJ D t[σ], D > 0 ∀ \, D∈ Sym(3)\0\ equation to show that for a given isotropic Cauchy-elastic constitutive law B σ(B) in terms of the left Cauchy-Green tensor B = F FT, the induced fourth-order tangent stiffness tensor H ZJ(σ) is positive definite if and only if for σ( B):=σ(B), the strong monotonicity condition (TSTS-M++) in the logarithmic strain is satisfied. Thus (CSP) implies (TSTS-M++) and vice-versa, and both imply the invertibility of the hypo-elastic material law between the stress and strain rates given by the tensor H ZJ(σ). The same characterization remains true for the corotational Green-Naghdi rate as well as the corotational logarithmic rate, conferring the corotational stability postulate (CSP) together with the monotonicity in the logarithmic strain tensor (TSTS-M++) a far reaching generality. It is conjectured that this characterization of (CSP) holds for a large class of reasonable corotational rates. The result for the logarithmic rate is based on a novel chain rule for corotational derivatives of isotropic tensor functions.