Fitting coupled potential energy surfaces for large systems: Method and construction of a 3-state representation for phenol photodissociation in the full 33 internal degrees of freedom using multireference configuration interaction determined data

Zhu, Xiaolei; Yarkony, David R.

doi:10.1063/1.4857335

Cited by 97 publications

(68 citation statements)

References 164 publications

(116 reference statements)

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“…Instead, surface hopping trajectories based on Tully's fewest switches method, 28 as implemented in the ANT program, 29 are used to determine the set of nuclear configurations for which H d must accurately represent the electronic structure data if the nonadiabatic process at hand is to be well described. 21 We define the domain of definition as the subspace of nuclear coordinate space for which H d reliably reproduces the ab initio data. A procedure for its construction based on quasiclassical surface hopping trajectories has been described in Ref.…”

Section: Selection Of R Nmentioning

confidence: 99%

“…A procedure for its construction based on quasiclassical surface hopping trajectories has been described in Ref. 21 = −1500 cm −1 . As seen in detail below, this shift results in considerable improvement in the D 0 for producing CH 2 O, cis-HCOH, and trans-HCOH from ground state CH 2 OH with little impact on remaining structures, including those of the reported conical intersections, for which the biggest geometric change is ∼0.05 Å, in 1, 2 2 A conical intersections.…”

Section: Selection Of R Nmentioning

confidence: 99%

“…21 In other language, we determine a removable approximation 32 to the nonremovable ab initio determined…”

Section: F Derivative Couplings and The Diabatic Representationmentioning

confidence: 99%

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Multistate, multichannel coupled diabatic state representations of adiabatic states coupled by conical intersections. CH2OH photodissociation

Malbon

Yarkony

2017

The Journal of Chemical Physics

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A coupled diabatic state representation, H, of the 1, 2, 3 A states of CHOH suitable for the description of the three channel, three state photodissociation process CHOH(1 A) + hv → CHOH(2, 3 A) → CHO(X, A) + H, cis-CHOH + H, trans-CHOH + H, is reported. The representation is based on electronic structure data (energies, energy gradients, and derivative couplings) obtained exclusively from multireference configuration interaction single and double excitation wave functions. Diabat shifting is employed to improve the representation's agreement with accurate experimental energetics. A careful analysis of the numerous minima, saddle points, and conical intersection seams is reported. The computed T(3 A) ∼ 35 220 cm is in excellent agreement with the experimental estimate of 35 053 cm, and the computed channel dissociation energies, D, for CHO 9453 (10 160), cis-HCOH 30 310.2 (29 923), and trans-HCOH 28 799 (28 391) cm are in good accord with the measured values given parenthetically. These accurate energetics over a wide range of nuclear configurations strongly support the ability of this H to enable quality simulations of nonadiabatic dynamics.

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Section: Selection Of R Nmentioning

confidence: 99%

Section: Selection Of R Nmentioning

confidence: 99%

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Multistate, multichannel coupled diabatic state representations of adiabatic states coupled by conical intersections. CH2OH photodissociation

Malbon

Yarkony

2017

The Journal of Chemical Physics

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“…(6) was introduced and carefully analyzed in our recent work describing the representation of adiabatic potential energy surfaces coupled by conical intersections. 28 Here we provide a concise recapitulation of that analysis (Eqs. (7a)- (16)) sufficient to explain the present procedure.…”

Section: B N State Degeneraciesmentioning

confidence: 99%

On the description of conical intersections—A continuous representation of the local topography of seams of conical intersection of three or more electronic states: A generalization of the two state result

Zhu

Yarkony

2014

The Journal of Chemical Physics

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For conical intersections of two states (I,J = I + 1) the vectors defining the branching or g-h plane, the energy difference gradient vector g(I,J), and the interstate coupling vector h(I,J), can be made orthogonal by a one parameter rotation of the degenerate electronic eigenstates. The representation obtained from this rotation is used to construct the parameters that describe the vicinity of the conical intersection seam, the conical parameters, s(x)(I,J)(R), s(y)(I,J)(R), g(I,J)(R), and h(I,J)(R). As a result of the orthogonalization these parameters can be made continuous functions of R, the internuclear coordinates. In this work we generalize this notion to construct continuous parametrizations of conical intersection seams of three or more states. The generalization derives from a recently introduced procedure for using non-degenerate electronic states to construct coupled diabatic states that represent adiabatic states coupled by conical intersections. The procedure is illustrated using the seam of conical intersections of three states in parazolyl as an example.

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“…[116] Non-adiabatic reactions depicting failure of the Born-Oppenheimer approximation were similarly treated in 1932 by London, [117] with the more well known but more restricted treatment of Landau also appearing in that year. [11,12] Today diabatic models are widely used to depict most chemical processes including electron-transfer, [118][119][120][121] natural photosynthesis and organic photovoltaics, [122][123][124][125][126][127][128][129][130][131][132][133] chemical quantum computing, [134,135] racemization processes, [136,137] non-adiabatic photochemical reactions, [138][139][140][141][142][143][144][145][146][147][148] proton-transfer, hydrogen bonding, hydrogen-transfer, coupled electron-proton transfer reactions, general reactions, [149] and aromaticity. [150][151][152][153][154] An essential aspect of this modern pre-eminence is its connection with Hush's adiabatic theory of electron transfer.…”

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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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Fitting coupled potential energy surfaces for large systems: Method and construction of a 3-state representation for phenol photodissociation in the full 33 internal degrees of freedom using multireference configuration interaction determined data

Cited by 97 publications

References 164 publications

Multistate, multichannel coupled diabatic state representations of adiabatic states coupled by conical intersections. CH2OH photodissociation

Multistate, multichannel coupled diabatic state representations of adiabatic states coupled by conical intersections. CH2OH photodissociation

On the description of conical intersections—A continuous representation of the local topography of seams of conical intersection of three or more electronic states: A generalization of the two state result

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

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