Litcius/Paper detail

Neural network reactive force field for C, H, N, and O systems

Pilsun Yoo, Michael Sakano, Saaketh Desai, Md Mahbubul Islam, Peilin Liao, Alejandro Strachan

2021npj Computational Materials88 citationsDOIOpen Access PDF

Abstract

Abstract Reactive force fields have enabled an atomic level description of a wide range of phenomena, from chemistry at extreme conditions to the operation of electrochemical devices and catalysis. While significant insight and semi-quantitative understanding have been drawn from such work, the accuracy of reactive force fields limits quantitative predictions. We developed a neural network reactive force field (NNRF) for CHNO systems to describe the decomposition and reaction of the high-energy nitramine 1,3,5-trinitroperhydro-1,3,5-triazine (RDX). NNRF was trained using energies and forces of a total of 3100 molecules (11,941 geometries) and 15 condensed matter systems (32,973 geometries) obtained from density functional theory calculations with semi-empirical corrections to dispersion interactions. The training set is generated via a semi-automated iterative procedure that enables refinement of the NNRF until a desired accuracy is attained. The root mean square (RMS) error of NNRF on a testing set of configurations describing the reaction of RDX is one order of magnitude lower than current state of the art potentials.

Topics & Concepts

Force field (fiction)Density functional theoryDecompositionWork (physics)Current (fluid)Field (mathematics)Artificial neural networkRoot mean squareLondon dispersion forceRange (aeronautics)MoleculeChemistryMaterials scienceStatistical physicsComputational chemistryPhysicsComputer scienceThermodynamicsMathematicsQuantum mechanicsvan der Waals forceOrganic chemistryPure mathematicsMachine learningComposite materialMachine Learning in Materials ScienceAdvanced Chemical Physics StudiesFuel Cells and Related Materials