Litcius/Paper detail

Electron-Passing Neural Networks for Atomic Charge Prediction in Systems with Arbitrary Molecular Charge

Derek P. Metcalf, Andy Jiang, Steven A. Spronk, Daniel L. Cheney, C. David Sherrill

2020Journal of Chemical Information and Modeling40 citationsDOI

Abstract

Atomic charges are critical quantities in molecular mechanics and molecular dynamics, but obtaining these quantities requires heuristic choices based on atom typing or relatively expensive quantum mechanical computations to generate a density to be partitioned. Most machine learning efforts in this domain ignore total molecular charges, relying on overfitting and arbitrary rescaling in order to match the total system charge. Here, we introduce the electron-passing neural network (EPNN), a fast, accurate neural network atomic charge partitioning model that conserves total molecular charge by construction. EPNNs predict atomic charges very similar to those obtained by partitioning quantum mechanical densities but at such a small fraction of the cost that they can be easily computed for large biomolecules. Charges from this method may be used directly for molecular mechanics, as features for cheminformatics, or as input to any neural network potential.

Topics & Concepts

Artificial neural networkCharge (physics)OverfittingMolecular dynamicsComputationQuantumStatistical physicsComputer scienceHeuristicAtomic chargeElectronAtom (system on chip)AlgorithmPhysicsBiological systemQuantum mechanicsArtificial intelligenceMoleculeParallel computingBiologyMachine Learning in Materials ScienceComputational Drug Discovery MethodsProtein Structure and Dynamics