Construction of Quasi-diabatic Hamiltonians That Accurately Represent <i>ab Initio</i> Determined Adiabatic Electronic States Coupled by Conical Intersections for Systems on the Order of 15 Atoms. Application to Cyclopentoxide Photoelectron Detachment in the Full 39 Degrees of Freedom

Shen, Yifan; Yarkony, David R.

doi:10.1021/acs.jpca.0c02763

Cited by 22 publications

(47 citation statements)

References 71 publications

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“…For example, 356 data points were computed for the 15-atom cyclopentoxy molecule with MR-CISD(5,3)/cc-pVD(T)Z. 96 Respective calculations comprised 19,302,445 configuration state functions, and one reaction coordinate could be fitted in the diabatic basis. We also ran into a similar problem when fitting the excited states of the amino acid tyrosine containing 24 atoms, which also requires a multireference treatment.…”

Section: Data Sets For Excited Statesmentioning

confidence: 99%

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Machine Learning for Electronically Excited States of Molecules

2020

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Electronically excited states of molecules are at the heart of photochemistry, photophysics, as well as photobiology and also play a role in material science. Their theoretical description requires highly accurate quantum chemical calculations, which are computationally expensive. In this review, we focus on not only how machine learning is employed to speed up such excited-state simulations but also how this branch of artificial intelligence can be used to advance this exciting research field in all its aspects. Discussed applications of machine learning for excited states include excited-state dynamics simulations, static calculations of absorption spectra, as well as many others. In order to put these studies into context, we discuss the promises and pitfalls of the involved machine learning techniques. Since the latter are mostly based on quantum chemistry calculations, we also provide a short introduction into excited-state electronic structure methods and approaches for nonadiabatic dynamics simulations and describe tricks and problems when using them in machine learning for excited states of molecules.

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Section: Data Sets For Excited Statesmentioning

confidence: 99%

“…Additionally, if certain reaction coordinates have been shown to be important in experiments or previous studies, then it is favorable to include data from scans along these reaction coordinates. 96 , 175 …”

Section: Data Sets For Excited Statesmentioning

confidence: 99%

Machine Learning for Electronically Excited States of Molecules

2020

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“…(32) approximately, without the strict equality, to define quasi-diabatic states. [9][10][11][12][13][14][15][16][17] Approaches reviewed in this section form the traditional set of tools. The BO approximation is always made as the first step, with post-BO corrections introduced for more difficult cases.…”

Section: B Born-huang Ansatz and The Born-oppenheimer Approximationmentioning

confidence: 99%

“…While in general this cannot be done exactly, 8 there are procedures for defining approximate transformations. [9][10][11][12][13][14][15][16][17] The necessity for diabatization is a consequence of starting with the BO approximation.…”

Section: Introductionmentioning

confidence: 99%

Molecular second-quantized Hamiltonian: Electron correlation and non-adiabatic coupling treated on an equal footing

Sibaev

Polyak

Manby

et al. 2020

The Journal of Chemical Physics

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We introduce a new theoretical and computational framework for treating molecular quantum mechanics without the Born-Oppenheimer approximation. The molecular wavefunction is represented in a tensor-product space of electronic and vibrational basis functions, with electronic basis chosen to reproduce the mean-field electronic structure at all geometries. We show how to transform the Hamiltonian to a fully second quantized form with creation/annihilation operators for electronic and vibrational quantum particles; paving the way for polynomial-scaling approximations to the tensor-product space formalism. In addition, we make a proof-of-principle application of the new ansatz to the vibronic spectrum of C 2 .

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“…NAMD, the same 10 6 electronic structure calculations will be required to build the global PESs and coupling surfaces for a system with 3 nuclear DOF, assuming the calculations generate a dense 3-dimensional grid with 100 points per each DOF. Modern surface interpolation techniques aimed to overcome the "curse of dimensionality" by using the sparse grids and focusing on the relevant parts of PESs can push the number of DOF to 24-39 (8-13 atoms), for roughly the same number of electronic structure calculations(97)(98)(99). Constructing the vibronic Hamiltonian models commonly used with the MCTDH method is less computationally expensive.…”

mentioning

confidence: 99%

Modeling Spin-Crossover Dynamics

Mukherjee

Fedorov

Varganov

2021

Annu. Rev. Phys. Chem.

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In this article, we review nonadiabatic molecular dynamics (NAMD) methods for modeling spin-crossover transitions. First, we discuss different representations of electronic states employed in the grid-based and direct NAMD simulations. The nature of interstate couplings in different representations is highlighted, with the main focus on nonadiabatic and spin-orbit couplings. Second, we describe three NAMD methods that have been used to simulate spin-crossover dynamics, including trajectory surface hopping, ab initio multiple spawning, and multiconfiguration time-dependent Hartree. Some aspects of employing different electronic structure methods to obtain information about potential energy surfaces and interstate couplings for NAMD simulations are also discussed. Third, representative applications of NAMD to spin crossovers in molecular systems of different sizes and complexities are highlighted. Finally, we pose several fundamental questions related to spin-dependent processes. These questions should be possible to address with future methodological developments in NAMD. Expected final online publication date for the Annual Review of Physical Chemistry, Volume 72 is April 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Construction of Quasi-diabatic Hamiltonians That Accurately Represent ab Initio Determined Adiabatic Electronic States Coupled by Conical Intersections for Systems on the Order of 15 Atoms. Application to Cyclopentoxide Photoelectron Detachment in the Full 39 Degrees of Freedom

Cited by 22 publications

References 71 publications

Machine Learning for Electronically Excited States of Molecules

Machine Learning for Electronically Excited States of Molecules

Molecular second-quantized Hamiltonian: Electron correlation and non-adiabatic coupling treated on an equal footing

Modeling Spin-Crossover Dynamics

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