A constitutive model for elastomers tailored by ionic bonds and entanglements

TL;DR

This paper develops a micromechanical constitutive model for elastomers incorporating ionic bonds and entanglements, explaining their combined effect on mechanical properties like toughness, stiffness, and self-recovery, validated against experimental data.

Contribution

The work introduces a novel coupled model for elastomers with ionic bonds and entanglements, advancing understanding of their mechanical behavior and guiding material design.

Findings

Model accurately matches experimental tensile data.

Entanglement evolution influences stiffness and toughness.

Ionic bonds enable plastic deformation and enhance strength.

Abstract

Over the past decade or two, the concept has emerged of using multiple types of weak interactions simultaneously to enhance the mechanical properties of elastomers. These weak interactions include physical entanglements, hydrogen bonds, metal-coordination bonds, dynamic covalent bonds, and ionic bonds. The combination of entanglements and ionic bonding has been minimally explored and is particularly exciting because of the broad application space for polyelectrolytes. In this work, a constitutive model framework is developed to describe the response of elastomers with both ionic bonds and entanglements. We formulate a micromechanical model that couples together chain stretching, ionic bond slipping, and entanglement evolution. The ionic bonds provide toughness by enabling plastic deformation in comparison to covalently crosslinked material and add strength compared to a linear polymer. Evolution of the entanglement density is taken as a key mechanism that can govern stiffness, toughness, and self-recovery in elastomers. The model is used to match bulk polyelectrolytes with different fractions of ionic components under a variety of loading histories. The variations in material parameters are then used to help understand the relative importance of different governing mechanisms in the bulk polymers. We show that the theoretical framework can explain our experimental uniaxial tensile experimental results for polyelectrolytes. This model can help to design better material with high stiffness and toughness. We expect that our model can be extended to explain the mechanical behavior of other polyelectrolytes and other soft materials with a wide range of dynamic bonds.