# Molecular dynamics simulation for cross-linking processes and material   properties of epoxy resins with the first principle calculation combined with   global reaction route mapping algorithms

**Authors:** Yutaka Oya, Masahiro Nakazawa, Keiichi Shirasu, Yuki Hino, Kyosuke, Inuyama, Gota Kikugawa, Jing Li, Riichi Kuwahara, Naoki Kishimoto, Hiroki, Waizumi, Masaaki Nishikawa, Anthony Waas, Nobuyuki Odagiri, Andrew Koyanagi,, Marco Salviato, Tomonaga Okabe

arXiv: 1907.06829 · 2020-01-31

## TL;DR

This study combines quantum chemical calculations with molecular dynamics simulations to predict epoxy resin properties, providing a parameter-free approach to understanding cross-linking and material characteristics at the molecular level.

## Contribution

It introduces a novel method integrating first-principles calculations with global reaction route mapping to simulate epoxy curing without empirical parameters.

## Key findings

- Higher cross-linking density improves mechanical properties.
- The method accurately predicts glass transition temperature and Young's modulus.
- Multi-functional groups enhance curing efficiency and material strength.

## Abstract

Herein, epoxy resin is cured by coupling quantum chemical (QC) calculations with molecular dynamics (MD) simulations that enable parameter-free prediction of material characteristics. A polymer network is formed by the reaction between base resin and curing agent. The reaction uses activation energy and heat of formation data obtained by first-principle calculations coupled with global reaction route mapping (GRRM) algorithms. Density, glass transition temperature, Young's modulus, and curing conversion is used to validate the procedure. Experimental and simulation results indicate that base resin with multi-functional reaction groups increases glass-transition temperature and Young's modulus because of cross-linked formations at the molecular scale.

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Source: https://tomesphere.com/paper/1907.06829