Generalised invariants and pseudo-universal relationships for hyperelastic materials: a new approach to constitutive modelling

<p>Constitutive modelling of nonlinear isotropic elastic materials requires a general formulation of the strainenergy function in terms of invariants, or equivalently in terms of the principal stretches {&lambda;1, &lambda;2, &lambda;3}. Yet, when choosing a particular form of a model, the representation in terms of either the principal invariants or stretches becomes important, since a judicious choice between one or the other can lead to a better encapsulation and interpretation of much of the behaviour of a given material. Here, we introduce a family of generalised isotropic invariants, including a member J&alpha; = &lambda; &alpha; 1 +&lambda; &alpha; 2 +&lambda; &alpha; 3 , which collapses to the classical first and second invariant of incompressible elasticity when &alpha; is 2 or -2, respectively. Then, we consider incompressible materials for which the strain-energy can be approximated by a function W that solely depends on this invariant J&alpha;. A natural question is to find &alpha; that best captures the finite deformation of a given material. We first show that there exist pseudo-universal relationships that are independent of the choice of W, and which only depend on &alpha;. Then, on using these pseudo-universal relationships, we show that one can obtain the exponent &alpha; that best fits a given dataset before seeking a functional form for the strain-energy function W. This two-step process delivers the best model that is a function of a single invariant. We show, on using specific examples, that this procedure leads to an excellent and easy to use approximation of constitutive models.</p>