posted on 2024-07-30, 06:05authored byDonald Bistri, Ignacio Arretche, Jacob J. Lessard, Michael Zakoworotny, Sagar Vyas, Laurence Rongy, Rafael Gómez-Bombarelli, Jeffrey S. Moore, Philippe Geubelle
Frontal ring-opening metathesis polymerization (FROMP)
involves
a self-perpetuating exothermic reaction, which enables the rapid and
energy-efficient manufacturing of thermoset polymers and composites.
Current state-of-the-art reaction–diffusion FROMP models rely
on a phenomenological description of the olefin metathesis kinetics,
limiting their ability to model the governing thermo-chemical FROMP
processes. Furthermore, the existing models are unable to predict
the variations in FROMP kinetics with changes in the resin composition
and as a result are of limited utility toward accelerated discovery
of new resin formulations. In this work, we formulate a chemically
meaningful model grounded in the established mechanism of ring-opening
metathesis polymerization (ROMP). Our study aims to validate the hypothesis
that the ROMP mechanism, applicable to monomer-initiator solutions
below 100 °C, remains valid under the nonideal conditions encountered
in FROMP, including ambient to >200 °C temperatures, sharp
temperature
gradients, and neat monomer environments. Through extensive simulations,
we demonstrate that our mechanism-based model accurately predicts
the FROMP behavior across various resin compositions, including polymerization
front velocities and thermal characteristics (e.g., Tmax). Additionally, we introduce a semi-inverse workflow
that predicts FROMP behavior from a single experimental data point.
Notably, the physiochemical parameters utilized in our model can be
obtained through DFT calculations and minimal experiments, highlighting
the model’s potential for rapid screening of new FROMP chemistries
in pursuit of thermoset polymers with superior thermo-chemo-mechanical
properties.