A new constitutive model for tetragonal energetic single crystals

TL;DR

This paper introduces a novel single crystal plasticity model specifically for tetragonal energetic crystals, capturing anisotropic yield behavior and enabling detailed simulations of explosive materials under dynamic loading.

Contribution

The paper develops a new tetragonal yield criterion based on tensor representation theorems, tailored for energetic crystals, and demonstrates its application through finite-element simulations of explosive response.

Findings

The model accurately describes the anisotropic plasticity of tetragonal crystals.

Simulations reveal the influence of crystalline anisotropy on explosive behavior.

The approach enhances understanding of thermo-mechanical responses in energetic materials.

Abstract

In this paper is presented a new single crystal plasticity model with yielding accounting for the tetragonal symmetry of molecular energetic crystals. This new tetragonal yield criterion has been developed using representation theorems for anisotropic tensor functions. It is defined for any type of loadings and depends on the characteristics of the tetragonal lattice (c/a ratio). It involves three independent plastic anisotropy parameters that can be expressed analytically in terms of the uniaxial yield stresses along four crystallographic directions. Illustration of the capabilities of this model is done for a pentaerythritol tetranitrate (PETN) crystal. Moreover, we present finite-element meso-scale simulations of the response of a polymer bonded explosive for which the behavior of the constituent energetic molecular crystals is described with an elastic/plastic model with yielding governed by the new single-crystal tetragonal criterion. The simulation results provide insights into the role played by the anisotropic crystalline plasticity and interactions between crystals on the thermo-mechanical response under dynamic compression of the PETN-based polymer bonded explosive (PBX) aggregate.