On Constructing the Asymptotic Solutions for Phase Transitions in a Slender Cylinder Composed of a Compressible Hyperelastic Material with Clamped End Conditions

Abstract

In this paper, we study phase transitions in a slender circular cylinder composed of a compressible hyperelastic material with a non-convex strain energy function. We aim to construct the asymptotic solutions based on an axisymmetrical three-dimensional setting and use the results to describe the key features (in particular, instability phenomena) observed in the experiments by others. The difficult problem of the solution bifurcations of the governing nonlinear partial differential equations (PDE's) is solved through a novel approach. By using a methodology involving coupled series-asymptotic expansions, we derive the normal form equation of the original complicated system of nonlinear PDE's. By writing the normal form equation into a first-order dynamical system and with a phase-plane analysis, we manage to deduce the global bifurcation properties and to solve the boundary-value problem analytically. The asymptotic solutions (including post-bifurcation solutions) in terms of integrals are obtained. The engineering stress-strain curve plotted from the asymptotic solutions can capture the key features of the curve measured in a few experiments (e.g., the stress drop, the stress plateau, and the small stress valley). It appears that the asymptotic solutions obtained shed certain light on the instability phenomena associated with phase transitions in a cylinder, in particular the role played by the radius-length ratio. Also, an important feature of this work is that we consider the clamped end conditions, which are more practical but rarely used in literature for phase transition problems.