Litcius/Paper detail

The Rise of Neural Networks for Materials and Chemical Dynamics

Maksim Kulichenko, Justin S. Smith, Benjamin Nebgen, Ying Wai Li, Nikita Fedik, Alexander I. Boldyrev, Nicholas Lubbers, Kipton Barros, Sergei Tretiak

2021The Journal of Physical Chemistry Letters100 citationsDOIOpen Access PDF

Abstract

Machine learning (ML) is quickly becoming a premier tool for modeling chemical processes and materials. ML-based force fields, trained on large data sets of high-quality electron structure calculations, are particularly attractive due their unique combination of computational efficiency and physical accuracy. This Perspective summarizes some recent advances in the development of neural network-based interatomic potentials. Designing high-quality training data sets is crucial to overall model accuracy. One strategy is active learning, in which new data are automatically collected for atomic configurations that produce large ML uncertainties. Another strategy is to use the highest levels of quantum theory possible. Transfer learning allows training to a data set of mixed fidelity. A model initially trained to a large data set of density functional theory calculations can be significantly improved by retraining to a relatively small data set of expensive coupled cluster theory calculations. These advances are exemplified by applications to molecules and materials.

Topics & Concepts

Computer scienceFidelityArtificial neural networkSet (abstract data type)Data setRetrainingQuality (philosophy)Experimental dataArtificial intelligenceMachine learningPerspective (graphical)Density functional theoryChemistryMathematicsPhysicsComputational chemistryInternational tradeProgramming languageTelecommunicationsStatisticsBusinessQuantum mechanicsMachine Learning in Materials ScienceComputational Drug Discovery MethodsProtein Structure and Dynamics