Prediction of photodynamics of 200 nm excited cyclobutanone with linear response electronic structure and ab initio multiple spawning

Prediction of photodynamics of 200 nm excited cyclobutanone with linear response electronic structure and ab initio multiple spawning

Simulations of photochemical reaction dynamics have been a challenge to the theoretical chemistry community for some time. In an effort to determine the predictive character of current approaches, we predict the results of an upcoming ultrafast diffraction experiment on the photodynamics of cyclobut...

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Veröffentlicht in:The Journal of chemical physics 2024-06, Vol.160 (24)
Hauptverfasser: Hait, Diptarka, Lahana, Dean, Fajen, O. Jonathan, Paz, Amiel S. P., Unzueta, Pablo A., Rana, Bhaskar, Lu, Lixin, Wang, Yuanheng, Kjønstad, Eirik F., Koch, Henrik, Martínez, Todd J.
Format: Artikel
Sprache:eng
Schlagworte:
ab initio multiple spawning
coupled-cluster methods
Density functional theory
Electron diffraction
Electronic structure
linear response
organic compounds
Photochemical reactions
potential energy surfaces
quantum chemical dynamics
Rydberg states
Time dependence
time dependent density functional theory
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Zusammenfassung:Simulations of photochemical reaction dynamics have been a challenge to the theoretical chemistry community for some time. In an effort to determine the predictive character of current approaches, we predict the results of an upcoming ultrafast diffraction experiment on the photodynamics of cyclobutanone after excitation to the lowest lying Rydberg state (S2). A picosecond of nonadiabatic dynamics is described with ab initio multiple spawning. We use both time dependent density functional theory (TDDFT) and equation-of-motion coupled cluster singles and doubles (EOM-CCSD) theory for the underlying electronic structure theory. We find that the lifetime of the S2 state is more than a picosecond (with both TDDFT and EOM-CCSD). The predicted ultrafast electron diffraction spectrum exhibits numerous structural features, but weak time dependence over the course of the simulations.
ISSN:0021-9606
1089-7690
1089-7690
DOI:10.1063/5.0203800