A theoretical study of the time-resolved x-ray absorption spectrum of the photoionized BT-1T cation

The time-resolved x-ray absorption spectrum of the BT-1T cation (BT-1T+) is theoretically simulated in order to investigate the charge transfer reaction of the system. We employ both trajectory surface hopping and quantum dynamics to simulate the structural evolution over time and the changes in the...

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Bibliographic Details
Published in:Structural dynamics (Melville, N.Y.) N.Y.), 2023-05, Vol.10 (3), p.034102-034102
Main Authors: Schnack-Petersen, Anna Kristina, Pápai, Mátyás, Coriani, Sonia, Møller, Klaus Braagaard
Format: Article
Language:English
Subjects:
Absorption spectra
Approximation
Cations
Charge transfer
Density functional theory
Mathematical analysis
Photoionization
Photovoltaic cells
Populations
Quantum theory
Simulation
Spectrum analysis
Time dependence
X ray absorption
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Summary:The time-resolved x-ray absorption spectrum of the BT-1T cation (BT-1T+) is theoretically simulated in order to investigate the charge transfer reaction of the system. We employ both trajectory surface hopping and quantum dynamics to simulate the structural evolution over time and the changes in the state populations. To compute the static x-ray absorption spectra (XAS) of the ground and excited states, we apply both the time-dependent density functional theory and the coupled cluster singles and doubles method. The results obtained are in good agreement between the methods. It is, furthermore, found that the small structural changes that occur during the reaction have little effect on the static XAS. Hence, the tr-XAS can be computed based on the state populations determined from a nuclear dynamics simulation and one set of static XAS calculations, utilizing the ground state optimized geometry. This approach can save considerable computational resources, as the static spectra need not to be calculated for all geometries. As BT-1T is a relatively rigid molecule, the outlined approach should only be considered when investigating non-radiative decay processes in the vicinity of the Franck–Condon point.
ISSN:2329-7778
2329-7778
DOI:10.1063/4.0000183