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dc.contributor.author
Omiya, Keita
dc.contributor.author
Nakagawa, Yuya O.
dc.contributor.author
Koh, Sho
dc.contributor.author
Mizukami, Wataru
dc.contributor.author
Gao, Qi
dc.contributor.author
Kobayashi, Takao
dc.date.accessioned
2022-06-05T11:14:23Z
dc.date.available
2022-02-02T04:04:26Z
dc.date.available
2022-06-05T11:14:23Z
dc.date.issued
2022-02-08
dc.identifier.issn
1549-9618
dc.identifier.issn
1549-9626
dc.identifier.other
10.1021/acs.jctc.1c00877
en_US
dc.identifier.uri
http://hdl.handle.net/20.500.11850/530413
dc.description.abstract
Elucidating photochemical reactions is vital to understanding various biochemical phenomena and developing functional materials such as artificial photosynthesis and organic solar cells, albeit with notorious difficulty in both experiments and theories. The best theoretical way so far to analyze photochemical reactions at the level of ab initio electronic structure is the state-averaged multiconfigurational self-consistent field (SA-MCSCF) method. However, the exponential computational cost of classical computers with the increasing number of molecular orbitals hinders applications of SA-MCSCF for large systems we are interested in. Utilizing quantum computers was recently proposed as a promising approach to overcome such computational cost, dubbed as state-averaged orbital-optimized variational quantum eigensolver (SA-OO-VQE). Here, we extend a theory of SA-OO- VQE so that analytical gradients of energy can be evaluated by standard techniques that are feasible with near-term quantum computers. The analytical gradients, known only for the state-specific OO-VQE in previous studies, allow us to determine various characteristics of photochemical reactions such as the conical intersection (CI) points. We perform a proof-of-principle calculation of our methods by applying it to the photochemical cis-trans isomerization of 1,3,3,3-tetrafluoropropene. Numerical simulations of quantum circuits and measurements can correctly capture the photochemical reaction pathway of this model system, including the CI points. Our results illustrate the possibility of leveraging quantum computers for studying photochemical reactions.
en_US
dc.language.iso
en
en_US
dc.publisher
American Chemical Society
en_US
dc.title
Analytical Energy Gradient for State-Averaged Orbital-Optimized Variational Quantum Eigensolvers and Its Application to a Photochemical Reaction
en_US
dc.type
Journal Article
dc.date.published
2022-01-21
ethz.journal.title
Journal of Chemical Theory and Computation
ethz.journal.volume
18
en_US
ethz.journal.issue
2
en_US
ethz.journal.abbreviated
J Chem Theory Comput
ethz.pages.start
741
en_US
ethz.pages.end
748
en_US
ethz.identifier.wos
ethz.identifier.scopus
ethz.publication.place
Washington, DC
en_US
ethz.publication.status
published
en_US
ethz.date.deposited
2022-02-02T04:04:38Z
ethz.source
WOS
ethz.eth
yes
en_US
ethz.availability
Metadata only
en_US
ethz.rosetta.installDate
2022-06-05T11:14:29Z
ethz.rosetta.lastUpdated
2022-06-05T11:14:29Z
ethz.rosetta.versionExported
true
ethz.COinS
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