Litcius/Paper detail

Atomistic learning in the electronically grand-canonical ensemble

Xi Chen, Muammar El Khatib, Per Lindgren, Adam P. Willard, Andrew J. Medford, Andrew A. Peterson

2023npj Computational Materials27 citationsDOIOpen Access PDF

Abstract

Abstract A strategy is presented for the machine-learning emulation of electronic structure calculations carried out in the electronically grand-canonical ensemble. The approach relies upon a dual-learning scheme, where both the system charge and the system energy are predicted for each image. The scheme is shown to be capable of emulating basic electrochemical reactions at a range of potentials, and coupling it with a bootstrap-ensemble approach gives reasonable estimates of the prediction uncertainty. The method is also demonstrated to accelerate saddle-point searches, and to extrapolate to systems with one to five water layers. We anticipate that this method will allow for larger length- and time-scale simulations necessary for electrochemical simulations.

Topics & Concepts

EmulationComputer scienceSaddle pointGrand canonical ensembleEnsemble learningScheme (mathematics)Range (aeronautics)Microcanonical ensembleCanonical ensembleStatistical ensembleEnsemble forecastingStatistical physicsCoupling (piping)SaddleArtificial intelligenceMathematicsMathematical optimizationPhysicsMaterials scienceMathematical analysisGeometryComposite materialStatisticsMetallurgyEconomic growthEconomicsMonte Carlo methodMachine Learning in Materials ScienceElectrochemical Analysis and ApplicationsCatalysis and Oxidation Reactions