We develop a new simulation technique based on path-integral molecular dynamics for calculating ground-state tunneling splitting patterns from ratios of symmetrized partition functions. In particular, molecular systems are rigorously projected onto their J = 0 rotational state by an “Eckart spring” that connects two adjacent beads in a ring polymer. Using this procedure, the tunneling splitting can be obtained from thermodynamic integration at just one (sufficiently low) temperature. Converged results are formally identical to the values that would have been obtained by solving the full rovibrational Schrödinger equation on a given Born-Oppenheimer potential energy surface. The new approach is showcased with simulations of hydronium and methanol, which are in good agreement with wavefunction-based calculations and experimental measurements. The method will be of particular use for the study of low-barrier methyl rotations and other floppy modes, where instanton theory is not valid.

Trenins, G., Meuser, L., Bertschi, H., Vavourakis, O., Flutsch, R., Richardson, J. (2023). Exact tunneling splittings from symmetrized path integrals. THE JOURNAL OF CHEMICAL PHYSICS, 159(3) [10.1063/5.0158879].

Exact tunneling splittings from symmetrized path integrals

Meuser L.;
2023

Abstract

We develop a new simulation technique based on path-integral molecular dynamics for calculating ground-state tunneling splitting patterns from ratios of symmetrized partition functions. In particular, molecular systems are rigorously projected onto their J = 0 rotational state by an “Eckart spring” that connects two adjacent beads in a ring polymer. Using this procedure, the tunneling splitting can be obtained from thermodynamic integration at just one (sufficiently low) temperature. Converged results are formally identical to the values that would have been obtained by solving the full rovibrational Schrödinger equation on a given Born-Oppenheimer potential energy surface. The new approach is showcased with simulations of hydronium and methanol, which are in good agreement with wavefunction-based calculations and experimental measurements. The method will be of particular use for the study of low-barrier methyl rotations and other floppy modes, where instanton theory is not valid.
Articolo in rivista - Articolo scientifico
Tunneling Splittings, Path Integral Molecular Dynamics
English
2023
159
3
034108
none
Trenins, G., Meuser, L., Bertschi, H., Vavourakis, O., Flutsch, R., Richardson, J. (2023). Exact tunneling splittings from symmetrized path integrals. THE JOURNAL OF CHEMICAL PHYSICS, 159(3) [10.1063/5.0158879].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/469265
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