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Fast Quasi-Centroid Molecular Dynamics for Water and Ice

Joseph E. Lawrence, Annina Z. Lieberherr, Theo Fletcher, David E. Manolopoulos

2023The Journal of Physical Chemistry B12 citationsDOIOpen Access PDF

Abstract

We describe how the fast quasi-centroid molecular dynamics (f-QCMD) method can be applied to condensed-phase systems by approximating the quasi-centroid potential of mean force as a sum of inter- and intramolecular corrections to the classical interaction potential. The corrections are found by using a regularized iterative Boltzmann inversion procedure to recover the inter- and intramolecular quasi-centroid distribution functions obtained from a path integral molecular dynamics simulation. The resulting methodology is found to give good agreement with a previously published QCMD dipole absorption spectrum for liquid water and satisfactory agreement for ice. It also gives good agreement with spectra from a recent implementation of CMD that uses a precomputed elevated temperature potential of mean force. Modern centroid molecular dynamics methods, therefore, appear to be reaching a consensus regarding the impact of nuclear quantum effects on the vibrational spectra of water and ice.

Topics & Concepts

CentroidMolecular dynamicsDipoleIntramolecular forceSpectral linePath integral formulationPhysicsStatistical physicsQuantumMathematicsQuantum mechanicsGeometryQuantum, superfluid, helium dynamicsSpectroscopy and Quantum Chemical StudiesAtmospheric Ozone and Climate
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