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Describing proton transfer modes in shared proton systems with constrained nuclear–electronic orbital methods

Yuzhe Zhang, Xi Xu, Nan Yang, Zehua Chen, Yang Yang

2023The Journal of Chemical Physics28 citationsDOIOpen Access PDF

Abstract

Proton transfer is crucial in various chemical and biological processes. Because of significant nuclear quantum effects, accurate and efficient description of proton transfer remains a great challenge. In this Communication, we apply constrained nuclear-electronic orbital density functional theory (CNEO-DFT) and constrained nuclear-electronic orbital molecular dynamics (CNEO-MD) to three prototypical shared proton systems and investigate their proton transfer modes. We find that with a good description of nuclear quantum effects, CNEO-DFT and CNEO-MD can well describe the geometries and vibrational spectra of the shared proton systems. Such a good performance is in significant contrast to DFT and DFT-based ab initio molecular dynamics, which often fail for shared proton systems. As an efficient method based on classical simulations, CNEO-MD is promising for future investigations of larger and more complex proton transfer systems.

Topics & Concepts

ProtonDensity functional theoryMolecular dynamicsAb initioMolecular orbitalElectronic structureQuantumTransfer (computing)Nuclear densityAtomic physicsPhysicsChemistryComputational chemistryMoleculeComputer scienceQuantum mechanicsParallel computingNuclear matterNucleonAdvanced Chemical Physics StudiesSpectroscopy and Quantum Chemical StudiesSolid-state spectroscopy and crystallography
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