Litcius/Paper detail

First-Principles-Based Machine-Learning Molecular Dynamics for Crystalline Polymers with van der Waals Interactions

Sung Jun Hong, Hoje Chun, Je-Hyun Lee, Byung‐Hyun Kim, Min Ho Seo, Joonhee Kang, Byungchan Han

2021The Journal of Physical Chemistry Letters31 citationsDOI

Abstract

Machine-learning (ML) techniques have drawn an ever-increasing focus as they enable high-throughput screening and multiscale prediction of material properties. Especially, ML force fields (FFs) of quantum mechanical accuracy are expected to play a central role for the purpose. The construction of ML-FFs for polymers is, however, still in its infancy due to the formidable configurational space of its composing atoms. Here, we demonstrate the effective development of ML-FFs using kernel functions and a Gaussian process for an organic polymer, polytetrafluoroethylene (PTFE), with a data set acquired by first-principles calculations and ab initio molecular dynamics (AIMD) simulations. Even though the training data set is sampled only with short PTFE chains, structures of longer chains optimized by our ML-FF show an excellent consistency with density functional theory calculations. Furthermore, when integrated with molecular dynamics simulations, the ML-FF successfully describes various physical properties of a PTFE bundle, such as a density, melting temperature, coefficient of thermal expansion, and Young’s modulus.

Topics & Concepts

Molecular dynamicsvan der Waals forcePolymerMaterials scienceDensity functional theoryConsistency (knowledge bases)Statistical physicsChemical physicsComputer scienceComputational chemistryMoleculeComposite materialChemistryPhysicsArtificial intelligenceQuantum mechanicsMachine Learning in Materials ScienceFuel Cells and Related MaterialsComputational Drug Discovery Methods
First-Principles-Based Machine-Learning Molecular Dynamics for Crystalline Polymers with van der Waals Interactions | Litcius