Derivative couplings and analytic gradients for diabatic states, with an implementation for Boys-localized configuration-interaction singles

Shervin Fatehi; Ethan Alguire; Joseph E. Subotnik

doi:10.1063/1.4820485

Derivative couplings and analytic gradients for diabatic states, with an implementation for Boys-localized configuration-interaction singles

Shervin Fatehi, Ethan Alguire, Joseph E. Subotnik

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

We demonstrate that Boys-localized diabatic states do indeed exhibit small derivative couplings, as is required of quasidiabatic states. In doing so, we present a general formalism for calculating derivative couplings and analytic gradients for diabatic states. We then develop additional equations specific to the case of Boys-localized configuration-interaction singles (CIS) - in particular, the analytic gradient of the CIS dipole matrix - and we validate our implementation against finite-difference results. In a forthcoming paper, we will publish additional algorithmic and computational details and apply our method to the Closs energy-transfer systems as a further test of the validity of Boys-localized diabatic states.

Original language	English (US)
Article number	124112
Journal	Journal of Chemical Physics
Volume	139
Issue number	12
DOIs	https://doi.org/10.1063/1.4820485
State	Published - Sep 28 2013
Externally published	Yes

All Science Journal Classification (ASJC) codes

General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1063/1.4820485

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abstract = "We demonstrate that Boys-localized diabatic states do indeed exhibit small derivative couplings, as is required of quasidiabatic states. In doing so, we present a general formalism for calculating derivative couplings and analytic gradients for diabatic states. We then develop additional equations specific to the case of Boys-localized configuration-interaction singles (CIS) - in particular, the analytic gradient of the CIS dipole matrix - and we validate our implementation against finite-difference results. In a forthcoming paper, we will publish additional algorithmic and computational details and apply our method to the Closs energy-transfer systems as a further test of the validity of Boys-localized diabatic states.",

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Y1 - 2013/9/28

N2 - We demonstrate that Boys-localized diabatic states do indeed exhibit small derivative couplings, as is required of quasidiabatic states. In doing so, we present a general formalism for calculating derivative couplings and analytic gradients for diabatic states. We then develop additional equations specific to the case of Boys-localized configuration-interaction singles (CIS) - in particular, the analytic gradient of the CIS dipole matrix - and we validate our implementation against finite-difference results. In a forthcoming paper, we will publish additional algorithmic and computational details and apply our method to the Closs energy-transfer systems as a further test of the validity of Boys-localized diabatic states.

AB - We demonstrate that Boys-localized diabatic states do indeed exhibit small derivative couplings, as is required of quasidiabatic states. In doing so, we present a general formalism for calculating derivative couplings and analytic gradients for diabatic states. We then develop additional equations specific to the case of Boys-localized configuration-interaction singles (CIS) - in particular, the analytic gradient of the CIS dipole matrix - and we validate our implementation against finite-difference results. In a forthcoming paper, we will publish additional algorithmic and computational details and apply our method to the Closs energy-transfer systems as a further test of the validity of Boys-localized diabatic states.

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ER -

Derivative couplings and analytic gradients for diabatic states, with an implementation for Boys-localized configuration-interaction singles

Abstract

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