A constitutive condition for idealized isotropic Cauchy elasticity involving the logarithmic strain

Abstract

Following Hill and Leblond, the aim of our work is to show, for isotropic nonlinear elasticity, a relation between the corotational Zaremba-Jaumann objective derivative of the Cauchy stress σ, i.e. equation D ZJ D t[σ] = d dt[σ] - W \, σ + σ \, W, W = skew( F \, F-1) equation and a constitutive requirement involving the logarithmic strain tensor. Given the deformation tensor F = D , the left Cauchy-Green tensor B = F \, FT, and the strain-rate tensor D = sym( F \, F-1), we show that equation eqCPSdef alignedat2 ∀ \,D∈ Sym(3) \! \! \0\: ~ D ZJ D t[σ],D > 0 & B σ( B) \;is strongly Hilbert-monotone & sym D B σ( B) ∈ Sym++4(6) (TSTS-M++), alignedat 1 equation where Sym++4(6) denotes the set of positive definite, (minor and major) symmetric fourth order tensors. We call the first inequality ``corotational stability postulate'' (CSP), a novel concept, which implies the True-Stress True-Strain strict Hilbert-Monotonicity (TSTS-M+) for B σ(B) = σ( B), i.e. equation σ( B1)-σ( B2), B1- B2 > 0 ∀ \, B1≠ B2∈ Sym++(3) \, . equation In this paper we expand on the ideas of Hill and Leblond, extending Leblonds calculus to the Cauchy elastic case.