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Molecular force fields with gradient-domain machine learning (GDML): Comparison and synergies with classical force fields

Huziel E. Sauceda, Michael Gastegger, Stefan Chmiela, Klaus‐Robert Müller, Alexandre Tkatchenko

2020The Journal of Chemical Physics52 citationsDOIOpen Access PDF

Abstract

Modern machine learning force fields (ML-FF) are able to yield energy and force predictions at the accuracy of high-level ab initio methods, but at a much lower computational cost. On the other hand, classical molecular mechanics force fields (MM-FF) employ fixed functional forms and tend to be less accurate, but considerably faster and transferable between molecules of the same class. In this work, we investigate how both approaches can complement each other. We contrast the ability of ML-FF for reconstructing dynamic and thermodynamic observables to MM-FFs in order to gain a qualitative understanding of the differences between the two approaches. This analysis enables us to modify the generalized AMBER force field by reparametrizing short-range and bonded interactions with more expressive terms to make them more accurate, without sacrificing the key properties that make MM-FFs so successful.

Topics & Concepts

Force field (fiction)ObservableComplement (music)Computer scienceDomain (mathematical analysis)Work (physics)Field (mathematics)Range (aeronautics)Ab initioStatistical physicsClass (philosophy)Artificial intelligenceClassical mechanicsPhysicsMathematicsMaterials scienceChemistryMathematical analysisQuantum mechanicsGenePure mathematicsComplementationPhenotypeBiochemistryComposite materialMachine Learning in Materials ScienceComputational Drug Discovery MethodsProtein Structure and Dynamics
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