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Predicting Chemical Recyclability Thermodynamics via Molecular Simulations

Vincent Nieboer, Peter Olsén, Karin Odelius, Jakob Wohlert

2024Macromolecules9 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Designing the next generation of circular plastics can contribute to preventing environmental pollution and the loss of embedded value. In light of this, assessing the thermodynamic parameters, i.e., the polymerization enthalpy (Δ H p ) and entropy (Δ S p ) of ring-opening polymerization, is becoming increasingly important as these directly connect to the chemical recyclability of polymers. However, determining the thermodynamics currently requires the synthesis of each monomer and polymer structure, consuming large amounts of time and chemicals, making it unfeasible to screen a myriad of different structures to find polymers with optimal properties and recyclability. In silico methods could mitigate these issues and drastically increase the rate at which new recyclable plastics can be developed. We demonstrate how the collision frequency between the reactive groups in polymers and monomers, derived from nonreactive (i.e., no chemical changes) molecular dynamics simulations, can be used for the simultaneous computation of Δ H p and Δ S p with respective 3.5 kJ mol –1 and 6.7 J mol –1 K –1 average deviation from experimental data.

Topics & Concepts

ThermodynamicsChemical thermodynamicsChemistryMaterials scienceNon-equilibrium thermodynamicsPhysicsCatalysis for Biomass ConversionChemistry and Chemical EngineeringCarbon dioxide utilization in catalysis
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