The rigidity transition in polymer melts with van der Waals interactions

TL;DR

This study investigates the emergence of rigidity in polymer melts near the glass transition using a Lennard-Jones bead-spring model, analyzing mechanical and dynamical properties through simulations.

Contribution

It provides a detailed analysis of the rigidity transition in polymer melts, highlighting the temperature T_1 where long-time rigidity appears, below the glass transition.

Findings

Polymeric glass shows long-time rigidity only below T_1.

The system's response to shear varies between local and global effects.

Both linear and non-linear relaxation regimes are characterized.

Abstract

We study the onset of rigidity near the glass transition (GT) in a short-chain polymer melt modelled by a bead-spring model, where all beads interact with Lennard-Jones potentials. The properties of the system are examined above and below the GT. In order to minimize high cooling-rate effects and computational times, equilibrium configurations are reached via isothermal compression. We monitor quantities such as the heat capacity C_P, the short-time diffusion constants D, the viscosity \eta, and the shear modulus; the time-dependent shear modulus G(t) is compared with the shear modulus \mu obtained from an externally applied instantaneous shear. We give a detailed analysis of the effects of such shearing on the system, both locally and globally. It is found that the polymeric glass only displays long-time rigid behavior below a temperature T_1, where T_1<T_G. Furthermore, the linear and non-linear relaxation regimes under applied shear are discussed.