Open AccessTunneling Splittings in Water Clusters from Path Integral Molecular Dynamics
Author(s) -
Christophe L. Vaillant,
David J. Wales,
Stuart C. Althorpe
Publication year - 2019
Publication title -
the journal of physical chemistry letters
Language(s) - English
Resource type - Journals
ISSN - 1948-7185
DOI - 10.1021/acs.jpclett.9b02951
Subject(s) - instanton , semiclassical physics , quantum tunnelling , potential energy surface , molecular dynamics , path integral formulation , water dimer , physics , trimer , chemistry , potential energy , scaling , molecular physics , quantum , quantum mechanics , ab initio , dimer , molecule , geometry , nuclear magnetic resonance , hydrogen bond , mathematics
We present calculations of tunneling splittings in selected small water clusters, based on a recently developed path integral molecular dynamics (PIMD) method. The ground-rotational-state tunneling motions associated with the largest splittings in the water dimer, trimer, and hexamer are considered, and we show that the PIMD predictions are in very good agreement with benchmark quantum and experimental results. As the tunneling spectra are highly sensitive to both the details of the quantum dynamics and the potential energy surface, our calculations are a validation of the MB-Pol surface as well as the accuracy of PIMD. The favorable scaling of PIMD with system size paves the way for calculations of tunneling splittings in large, nonrigid molecular systems with motions that cannot be treated accurately by other methods, such as the semiclassical instanton.
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