Close Search Advanced
Journals
Resources
About Us
Open Access

Review of Feynman's Path Integral in Quantum Statistics: From the Molecular Schrödinger Equation to Kleinert's Variational Perturbation Theory

Review of Feynman's Path Integral in Quantum Statistics: From the Molecular Schrödinger Equation to Kleinert's Variational Perturbation Theory
Read Now
Download (PDF)

Year:    2014

Communications in Computational Physics, Vol. 15 (2014), Iss. 4 : pp. 853–894

Abstract

Feynman's path integral reformulates the quantum Schrödinger differential equation to be an integral equation. It has been being widely used to compute internuclear quantum-statistical effects on many-body molecular systems. In this Review, the molecular Schrödinger equation will first be introduced, together with the Born-Oppenheimer approximation that decouples electronic and internuclear motions. Some effective semiclassical potentials, e.g., centroid potential, which are all formulated in terms of Feynman's path integral, will be discussed and compared. These semiclassical potentials can be used to directly calculate the quantum canonical partition function without individual Schrödinger's energy eigenvalues. As a result, path integrations are conventionally performed with Monte Carlo and molecular dynamics sampling techniques. To complement these techniques, we will examine how Kleinert's variational perturbation (KP) theory can provide a complete theoretical foundation for developing non-sampling/non-stochastic methods to systematically calculate centroid potential. To enable the powerful KP theory to be practical for many-body molecular systems, we have proposed a new path-integral method: automated integration-free path-integral (AIF-PI) method. Due to the integration-free and computationally inexpensive characteristics of our AIF-PI method, we have used it to perform ab initio path-integral calculations of kinetic isotope effects on proton-transfer and RNA-related phosphoryl-transfer chemical reactions. The computational procedure of using our AIF-PI method, along with the features of our new centroid path-integral theory at the minimum of the absolute-zero energy (AMAZE), are also highlighted in this review.

Submit Article

Journal Article Details

Publisher Name:    Global Science Press

Language:    English

DOI:    https://doi.org/10.4208/cicp.140313.070513s

Communications in Computational Physics, Vol. 15 (2014), Iss. 4 : pp. 853–894

Published online:    2014-01

AMS Subject Headings:    Global Science Press

Copyright:    COPYRIGHT: © Global Science Press

Pages:    42

Keywords:   

  1. Numerical Path Integral Approach to Quantum Dynamics and Stationary Quantum States

    Ruokosenmäki, Ilkka | Rantala, Tapio T.

    Communications in Computational Physics, Vol. 18 (2015), Iss. 1 P.91

    https://doi.org/10.4208/cicp.180914.161214a [Citations: 3]

  2. The 4D Dirac Equation in Five Dimensions

    Breban, Romulus

    Annalen der Physik, Vol. 530 (2018), Iss. 10

    https://doi.org/10.1002/andp.201800042 [Citations: 2]

  3. Pitfall in Free‐Energy Simulations on Simplest Systems

    Wong, Kin‐Yiu | Xu, Yuqing | Xu, Liang

    ChemistrySelect, Vol. 2 (2017), Iss. 16 P.4398

    https://doi.org/10.1002/slct.201601160 [Citations: 0]

  4. Estimation of frequency factors for the calculation of kinetic isotope effects from classical and path integral free energy simulations

    Giese, Timothy J. | York, Darrin M.

    The Journal of Chemical Physics, Vol. 158 (2023), Iss. 17

    https://doi.org/10.1063/5.0147218 [Citations: 1]

  5. Altered Mechanisms for Acid-Catalyzed RNA Cleavage and Isomerization Reactions Models

    Xu, Yuqing | Harris, Michael E. | York, Darrin M. | Wong, Kin-Yiu

    Journal of Chemical Theory and Computation, Vol. 19 (2023), Iss. 4 P.1322

    https://doi.org/10.1021/acs.jctc.2c01277 [Citations: 0]

  6. Ab initio path‐integral calculations of kinetic and equilibrium isotope effects on base‐catalyzed RNA transphosphorylation models

    Wong, Kin‐Yiu | Xu, Yuqing | York, Darrin M.

    Journal of Computational Chemistry, Vol. 35 (2014), Iss. 17 P.1302

    https://doi.org/10.1002/jcc.23628 [Citations: 14]

  7. Improved methods for Feynman path integral calculations and their application to calculate converged vibrational–rotational partition functions, free energies, enthalpies, entropies, and heat capacities for methane

    Mielke, Steven L. | Truhlar, Donald G.

    The Journal of Chemical Physics, Vol. 142 (2015), Iss. 4

    https://doi.org/10.1063/1.4905526 [Citations: 12]

  8. Review of computer simulations of isotope effects on biochemical reactions: From the Bigeleisen equation to Feynman's path integral

    Wong, Kin-Yiu | Xu, Yuqing | Xu, Liang

    Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics, Vol. 1854 (2015), Iss. 11 P.1782

    https://doi.org/10.1016/j.bbapap.2015.04.021 [Citations: 17]

  9. Theoretical Simulations of Kinetic Isotope Effects on Decarboxylation of 3‐Carboxybenzisoxazole

    Xu, Yuqing | Wong, Kin‐Yiu | Wang, Meishan

    ChemPhysChem, Vol. 24 (2023), Iss. 6

    https://doi.org/10.1002/cphc.202200571 [Citations: 0]

  10. McMillan-Mayer theory of solutions revisited: Simplifications and extensions

    Vafaei, Shaghayegh | Tomberli, Bruno | Gray, C. G.

    The Journal of Chemical Physics, Vol. 141 (2014), Iss. 15

    https://doi.org/10.1063/1.4897980 [Citations: 33]

  11. A low-rank approach to the computation of path integrals

    Litsarev, Mikhail S. | Oseledets, Ivan V.

    Journal of Computational Physics, Vol. 305 (2016), Iss. P.557

    https://doi.org/10.1016/j.jcp.2015.11.009 [Citations: 4]