Non-adiabatic effects in thermochemistry, spectroscopy and kinetics: The general importance of all three Born-Oppenheimer breakdown corrections

Reimers, JR; McKemmish, LK; McKenzie, RH; Hush, NS

Non-adiabatic effects in thermochemistry, spectroscopy and kinetics: The general importance of all three Born-Oppenheimer breakdown corrections

Reimers, JR

McKemmish, LK McKenzie, RH Hush, NS

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Publication Type:: Journal Article
Citation:: Physical Chemistry Chemical Physics, 2015, 17 (38), pp. 24641 - 24665
Issue Date:: 2015-07-03

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Field	Value	Language
dc.contributor.author	Reimers, JR https://orcid.org/0000-0001-5157-7422	en_US
dc.contributor.author	McKemmish, LK	en_US
dc.contributor.author	McKenzie, RH	en_US
dc.contributor.author	Hush, NS	en_US
dc.date.issued	2015-07-03	en_US
dc.identifier.citation	Physical Chemistry Chemical Physics, 2015, 17 (38), pp. 24641 - 24665	en_US
dc.identifier.issn	1463-9076	en_US
dc.identifier.uri	http://hdl.handle.net/10453/42192
dc.description.abstract	This journal is © the Owner Societies 2015. Using a simple model Hamiltonian, the three correction terms for Born-Oppenheimer (BO) breakdown, the adiabatic diagonal correction (DC), the first-derivative momentum non-adiabatic correction (FD), and the second-derivative kinetic-energy non-adiabatic correction (SD), are shown to all contribute to thermodynamic and spectroscopic properties as well as to thermal non-diabatic chemical reaction rates. While DC often accounts for >80% of thermodynamic and spectroscopic property changes, the commonly used practice of including only the FD correction in kinetics calculations is rarely found to be adequate. For electron-transfer reactions not in the inverted region, the common physical picture that diabatic processes occur because of surface hopping at the transition state is proven inadequate as the DC acts first to block access, increasing the transition state energy by (ω)<sup>2</sup>λ/16J<sup>2</sup> (where λ is the reorganization energy, J the electronic coupling and ω the vibration frequency). However, the rate constant in the weakly-coupled Golden-Rule limit is identified as being only inversely proportional to this change rather than exponentially damped, owing to the effects of tunneling and surface hopping. Such weakly-coupled long-range electron-transfer processes should therefore not be described as "non-adiabatic" processes as they are easily described by Born-Huang ground-state adiabatic surfaces made by adding the DC to the BO surfaces; instead, they should be called just "non-Born-Oppenheimer" processes. The model system studied consists of two diabatic harmonic potential-energy surfaces coupled linearly through a single vibration, the "two-site Holstein model". Analytical expressions are derived for the BO breakdown terms, and the model is solved over a large parameter space focusing on both the lowest-energy spectroscopic transitions and the quantum dynamics of coherent-state wavepackets. BO breakdown is investigated pertinent to: ammonia inversion, aromaticity in benzene, the Creutz-Taube ion, the bacterial photosynthetic reaction centre, BNB, the molecular conductor Alq3, and inverted-region charge recombination in a ferrocene-porphyrin-fullerene triad photosynthetic model compound. Throughout, the fundamental nature of BO breakdown is linked to the properties of the cusp catastrophe: the cusp diameter is shown to determine the magnitudes of all couplings, numerical basis-set and trajectory-integration requirements, and to determine the transmission coefficient κ used to understand deviations from transition-state theory.	en_US
dc.relation.ispartof	Physical Chemistry Chemical Physics	en_US
dc.relation.isbasedon	10.1039/c5cp02238j	en_US
dc.subject.classification	Chemical Physics	en_US
dc.subject.mesh	Ammonia	en_US
dc.subject.mesh	Benzene	en_US
dc.subject.mesh	Electron Transport	en_US
dc.subject.mesh	Kinetics	en_US
dc.subject.mesh	Electrons	en_US
dc.subject.mesh	Quantum Theory	en_US
dc.subject.mesh	Thermodynamics	en_US
dc.subject.mesh	Models, Chemical	en_US
dc.title	Non-adiabatic effects in thermochemistry, spectroscopy and kinetics: The general importance of all three Born-Oppenheimer breakdown corrections	en_US
dc.type	Journal Article
utslib.citation.volume	38	en_US
utslib.citation.volume	17	en_US
utslib.for	0204 Condensed Matter Physics	en_US
utslib.for	0306 Physical Chemistry (incl. Structural)	en_US
utslib.for	02 Physical Sciences	en_US
utslib.for	03 Chemical Sciences	en_US
utslib.for	09 Engineering	en_US
pubs.embargo.period	Not known	en_US
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Science
pubs.organisational-group	/University of Technology Sydney/Faculty of Science/School of Mathematical and Physical Sciences
utslib.copyright.status	closed_access
pubs.issue	38	en_US
pubs.publication-status	Published	en_US
pubs.volume	17	en_US

Abstract:

This journal is © the Owner Societies 2015. Using a simple model Hamiltonian, the three correction terms for Born-Oppenheimer (BO) breakdown, the adiabatic diagonal correction (DC), the first-derivative momentum non-adiabatic correction (FD), and the second-derivative kinetic-energy non-adiabatic correction (SD), are shown to all contribute to thermodynamic and spectroscopic properties as well as to thermal non-diabatic chemical reaction rates. While DC often accounts for >80% of thermodynamic and spectroscopic property changes, the commonly used practice of including only the FD correction in kinetics calculations is rarely found to be adequate. For electron-transfer reactions not in the inverted region, the common physical picture that diabatic processes occur because of surface hopping at the transition state is proven inadequate as the DC acts first to block access, increasing the transition state energy by (ω)²λ/16J² (where λ is the reorganization energy, J the electronic coupling and ω the vibration frequency). However, the rate constant in the weakly-coupled Golden-Rule limit is identified as being only inversely proportional to this change rather than exponentially damped, owing to the effects of tunneling and surface hopping. Such weakly-coupled long-range electron-transfer processes should therefore not be described as "non-adiabatic" processes as they are easily described by Born-Huang ground-state adiabatic surfaces made by adding the DC to the BO surfaces; instead, they should be called just "non-Born-Oppenheimer" processes. The model system studied consists of two diabatic harmonic potential-energy surfaces coupled linearly through a single vibration, the "two-site Holstein model". Analytical expressions are derived for the BO breakdown terms, and the model is solved over a large parameter space focusing on both the lowest-energy spectroscopic transitions and the quantum dynamics of coherent-state wavepackets. BO breakdown is investigated pertinent to: ammonia inversion, aromaticity in benzene, the Creutz-Taube ion, the bacterial photosynthetic reaction centre, BNB, the molecular conductor Alq3, and inverted-region charge recombination in a ferrocene-porphyrin-fullerene triad photosynthetic model compound. Throughout, the fundamental nature of BO breakdown is linked to the properties of the cusp catastrophe: the cusp diameter is shown to determine the magnitudes of all couplings, numerical basis-set and trajectory-integration requirements, and to determine the transmission coefficient κ used to understand deviations from transition-state theory.

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http://hdl.handle.net/10453/42192