Two types of compressible isotropic neo-Hookean material models

Abstract

In this contribution, we present a systematic study of the performance of two known types of compressible generalization of the incompressible neo-Hookean material model. The first type of generalization is based on the development of vol-iso neo-Hookean models and involves the additive decomposition of the elastic energy into volumetric and isochoric parts. The second simpler type of generalization is based on the development of mixed neo-Hookean models that do not use this decomposition. Theoretical studies of model performance and simulations of some homogeneous deformations have shown that when using volumetric functions (Jq+J-q-2)/(2q2) (J is the volume ratio, and q∈ R is a parameter, q≥ 0) from the Hartmann-Neff family [Hartmann and Neff, Int. J. Solids Structures, 40: 2767-2791 (2003)] with parameter q≥ 2 (the preferred value is q=5), mixed and vol-iso models show similar performance in applications and have physically reasonable responses in extreme states, which is convenient for theoretical studies. However, contrary to vol-iso models, mixed models allow the use of a wider set of volumetric functions with physically reasonable responses in extreme states. A further feature of mixed models is simpler expressions for stresses and tangent stiffness tensors.