The Importance of Motions that Accompany Those Occurring Along the Reaction Coordinate

Reimers, Jeffrey R.

doi:10.1071/ch15313

Cited by 7 publications

(7 citation statements)

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“…In its simplest analytical form as applied here, adiabatic electron-transfer theory assumes parabolic surfaces and includes only one type of nuclear motion, motion along the reaction coordinate. These assumptions lead to three limitations in its applicability to transition-state spectroscopy: i) often motions other than the reaction coordinate are critical to observed phenomena [4,[72][73][74], including continuous motions like solvent friction [75]; ii) conical intersections intrinsically involve at least two nuclear coordinates; and iii) many reactions of interest involve bimolecular processes that cannot easily be discussed using harmonic potentials. However, the basic model does provide an underlying basis for critical aspects of these more complicated phenomena.…”

Section: The Basic Model Used In Adiabatic Electron-transfer Theorymentioning

confidence: 99%

Relating transition-state spectroscopy to standard chemical spectroscopic processes

Reimers

Hush

2017

Chemical Physics Letters

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Transition-state spectra are mapped out using generalized adiabatic electron-transfer theory. This simple model depicts diverse chemical properties, from aromaticity, through bound reactions such as isomerizations and atom-transfer processes with classic transition states, to processes often described as being "non-adiabatic", to those in the "inverted" region that become slower as they are made more exothermic. Predictably, the Born-Oppenheimer approximation is found inadequate for modelling transition-state spectra in the weak-coupling limit. In this limit, the adiabatic Born-Huang approximation is found to perform much better than non-adiabatic surfacehopping approaches. Transition-state spectroscopy is shown to involve significant quantum entanglement between electronic and nuclear motion. Highlights-transition-state spectra are calculated over a wide parameter region-spectral and temporal responses may be simple or quite complex-surface hopping methods fail to describe spectra usually classified as "non-adiabatic"-transition-state spectroscopy embodies quantum entanglement

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Section: The Basic Model Used In Adiabatic Electron-transfer Theorymentioning

confidence: 99%

Relating transition-state spectroscopy to standard chemical spectroscopic processes

Reimers

Hush

2017

Chemical Physics Letters

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“…The critical feature is the universality of the model parameters for the qualitative description of system properties. Simple models can also be extended to universal quantitative ones provided that full quantum solutions [26,50], sufficient interfering processes [43,[51][52], and motions orthogonal to the reaction coordinate are also included [27,[53][54]. The assignment [55] of the Q-band spectrum of chlorophyll-a, arguably the world's most important chromophore whose properties display a strong pseudo-Jahn-Teller effect, following 50 years of intense debate, provides another example of the power of this approach.…”

Section: Related Contentmentioning

confidence: 99%

Diabatic models with transferrable parameters for generalized chemical reactions

Reimers

McKemmish

McKenzie

et al. 2017

J. Phys.: Conf. Ser.

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Abstract. Diabatic models applied to adiabatic electron-transfer theory yield many equations involving just a few parameters that connect ground-state geometries and vibration frequencies to excited-state transition energies and vibration frequencies to the rate constants for electrontransfer reactions, utilizing properties of the conical-intersection seam linking the ground and excited states through the Pseudo Jahn-Teller effect. We review how such simplicity in basic understanding can also be obtained for general chemical reactions. The key feature that must be recognized is that electron-transfer (or hole transfer) processes typically involve one electron (hole) moving between two orbitals, whereas general reactions typically involve two electrons or even four electrons for processes in aromatic molecules. Each additional moving electron leads to new high-energy but interrelated conical-intersection seams that distort the shape of the critical lowest-energy seam. Recognizing this feature shows how conicalintersection descriptors can be transferred between systems, and how general chemical reactions can be compared using the same set of simple parameters. Mathematical relationships are presented depicting how different conical-intersection seams relate to each other, showing that complex problems can be reduced into an effective interaction between the ground-state and a critical excited state to provide the first semi-quantitative implementation of Shaik's "twin state" concept. Applications are made (i) demonstrating why the chemistry of the firstrow elements is qualitatively so different to that of the second and later rows, (ii) deducing the bond-length alternation in hypothetical cyclohexatriene from the observed UV spectroscopy of benzene, (iii) demonstrating that commonly used procedures for modelling surface hopping based on inclusion of only the first-derivative correction to the Born-Oppenheimer approximation are valid in no region of the chemical parameter space, and (iv), demonstrating the types of chemical reactions that may be suitable for exploitation as a chemical qubit in some quantum information processor. IntroductionThough chemical reactions involve complicated restructuring of the electronic and nuclear configuration and dynamics, it can be useful to use the simplification of envisaging reactions as occurring along a single reaction coordinate. This basic concept forms the conceptual framework of Transition-State Theory and much of modern chemistry. Modern electronic-structure calculation methods can predict wide ranges of properties to within the accuracy of experimental measurements, capturing all chemical and spectroscopic features of the system, but such approaches rarely provide insight into why processes occur and have to be repeated for each small system variation. Diabatic models can be used to interpret these calculations, however, revealing the chemical features controlling the process. Basically, simple forms, called diabatic surfaces, are used to describe the reactants and pro...

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“…Reproduced from ref. [178], with permission of CSIRO Publishing. in 1950 demonstrated this effect for benzene. [13] Modern nanotechnological applications to which electron correlation is critical will be discussed also in later sections.…”

Section: From Understanding Benzene In 1946 To Understanding Chlorophmentioning

confidence: 99%

“…[107,108] This allowed the bacterial reaction centre cation to be understood completely, [99,102] facilitated assignment of the spectrum of Chl-a, [47] and led to the understanding of a range of phenomena where properties were determined by more than just the reaction coordinate, as has been recently reviewed. [178] It unified critical aspects of the works of Craig and of Hush, playing on the non-uniqueness of diabatic descriptions for chemical and spectroscopic phenomena. [179] Unification of basic theories for chemistry and spectroscopy touches the very foundations of chemical understanding.…”

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confidence: 99%

Putting David Craig’s Legacy to Work in Nanotechnology and Biotechnology

Reimers¹

2016

Aust. J. Chem.

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left us with a lasting legacy concerning basic understanding of chemical spectroscopy and bonding. This is expressed in terms of some of the recent achievements of my own research career, with a focus on integration of Craig's theories with those of Noel Hush to solve fundamental problems in photosynthesis, molecular electronics (particularly in regard to the molecules synthesized by Maxwell Crossley), and self-assembled monolayer structure and function. Reviewed in particular is the relation of Craig's legacy to: the 50-year struggle to assign the visible absorption spectrum of arguably the world's most significant chromophore, chlorophyll; general theories for chemical bonding and structure extending Hush's adiabatic theory of electron-transfer processes; inelastic electron-tunnelling spectroscopy (IETS); chemical quantum entanglement and the Penrose-Hameroff model for quantum consciousness; synthetic design strategies for NMR quantum computing; Gibbs free-energy measurements and calculations for formation and polymorphism of organic self-assembled monolayers on graphite surfaces from organic solution; and understanding the basic chemical processes involved in the formation of gold surfaces and nanoparticles protected by sulfur-bound ligands, ligands whose form is that of Au 0 -thiyl rather than its commonly believed Au I -thiolate tautomer.

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The Importance of Motions that Accompany Those Occurring Along the Reaction Coordinate

Cited by 7 publications

References 100 publications

Relating transition-state spectroscopy to standard chemical spectroscopic processes

Relating transition-state spectroscopy to standard chemical spectroscopic processes

Diabatic models with transferrable parameters for generalized chemical reactions

Putting David Craig’s Legacy to Work in Nanotechnology and Biotechnology

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