posted on 2022-08-30, 14:04authored byAlessandro Perego, Daria Lazarenko, Michel Cloitre, Fardin Khabaz
We implement a hybrid molecular dynamics/Monte Carlo
simulation
to study the microscopic dynamics and the macroscopic rheology of
vitrimers with a fast bond exchange rate. We show that the linear
viscoelastic properties and mean squared displacement of the vitrimers
collapse onto master curves by applying the same shift factors that
follow the Williams–Landel–Ferry equation at low temperatures
and Arrhenius-like behavior at high temperatures. The linkage between
the microscopic dynamics and the linear rheology of vitrimers is established
using the generalized Stokes–Einstein relationship, which efficiently
extends the timescale of simulations and predicts the viscoelasticity.
The values of the shift factors are related to the characteristic
decay time of the intermediate scattering function, which is accessible
in scattering experiments. The same results hold in the case of an
all-atom model of an ionic liquid. Our methodology provides a microscopic
basis for the time-superposition principle and predicts the macroscopic
rheology of thermo-rheologically simple vitrimers.