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Neural network potential energy surface for the low temperature ring polymer molecular dynamics of the H<sub>2</sub>CO + OH reaction.

Pablo del Mazo‐Sevillano, Alfredo Aguado, Octavio Roncero

2021PubMed23 citationsDOI

Abstract

O and HCOOH + H are presented. In this work, a source of spurious long range interactions in symmetry adapted neural network (NN) schemes is identified, which prevents their direct application for low temperature dynamical studies. For this reason, a partition of the PES into a diabatic matrix plus a NN many-body term has been used, fitted with a novel artificial neural network scheme that prevents spurious asymptotic interactions. Quasi-classical trajectory (QCT) and ring polymer molecular dynamics (RPMD) studies have been carried on this PES to evaluate the rate constant temperature dependence for the different reactive processes, showing good agreement with the available experimental data. Of special interest is the analysis of the previously identified trapping mechanism in the RPMD study, which can be attributed to spurious resonances associated with excitations of the normal modes of the ring polymer.

Topics & Concepts

Spurious relationshipDiabaticPotential energy surfaceWork (physics)Potential energyMolecular dynamicsArtificial neural networkRing (chemistry)TrajectoryMatrix (chemical analysis)Chemical physicsChemistryPhysicsStatistical physicsComputational chemistryAdiabatic processThermodynamicsClassical mechanicsMoleculeComputer scienceQuantum mechanicsMachine learningChromatographyOrganic chemistryQuantum, superfluid, helium dynamicsSpectroscopy and Quantum Chemical StudiesAdvanced Chemical Physics Studies
Neural network potential energy surface for the low temperature ring polymer molecular dynamics of the H<sub>2</sub>CO + OH reaction. | Litcius