Proton Transfer Studied Using a Combined Ab Initio Reactive Potential Energy Surface with Quantum Path Integral Methodology
Wong, Kim; Sonnenberg, Jason; Paesani, Francesco; Yamamoto, Takeshi; Vanicek, Jiri; Zhang, Wei; Schlegel, Bernhard; Case, David; Cheatham, Thomas III; Miller, William; Voth, Gregory
2010

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Abstract

The rates of intramolecular proton transfer are calculated on a full-dimensional reactive electronic potential energy surface that incorporates high-level ab initio calculations along the reaction path and by using classical transition state theory, path-integral quantum transition state theory, and the quantum instanton approach. The specific example problem studied is malonaldehyde. Estimates of the kinetic isotope effect using the latter two methods are found to be in reasonable agreement with each other. Improvements and extensions of this practical, yet chemically accurate framework for the calculations of quantized, reactive dynamics are also discussed.

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Title Proton Transfer Studied Using a Combined Ab Initio Reactive Potential Energy Surface with Quantum Path Integral Methodology
Author(s) Wong, Kim ; Sonnenberg, Jason ; Paesani, Francesco ; Yamamoto, Takeshi ; Vanicek, Jiri ; Zhang, Wei ; Schlegel, Bernhard ; Case, David ; Cheatham, Thomas III ; Miller, William ; Voth, Gregory
Published in Journal of Chemical Theory and Computation
Volume 6
Issue 9
Pages 2566-2580
Date 2010
ISSN 1549-9618
DOI https://doi.org/10.1021/ct900579k
Laboratories LCPT
Record Appears in Scientific production and competences > SB - School of Basic Sciences > ISIC - Institute of Chemical Sciences and Engineering > LCPT - Laboratory of Theoretical Physical Chemistry
Peer-reviewed publications
Work outside EPFL
Journal Articles
Published
Record creation date 2010-09-01

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