Ab initio simulation of single vibronic level fluorescence spectra of anthracene using Hagedorn wavepackets

• URL: http://arxiv.org/abs/2403.00702v3
• Date: Fri, 17 May 2024 16:15:42 GMT
• Title: Ab initio simulation of single vibronic level fluorescence spectra of anthracene using Hagedorn wavepackets
• Authors: Zhan Tong Zhang, Jiří J. L. Vaníček,
• Abstract summary: Single vibronic level (SVL) fluorescence spectroscopy contributes to the understanding of molecular vibrational structures and relaxation processes. Here, we present a practical method for computing SVL fluorescence spectra of polyatomic molecules from arbitrary initial vibrational levels.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Single vibronic level (SVL) fluorescence spectroscopy contributes to the understanding of molecular vibrational structures and relaxation processes. Here, we present a practical method for computing SVL fluorescence spectra of polyatomic molecules from arbitrary initial vibrational levels. This method, which combines a time-dependent approach using Hagedorn wavepackets with accurate evaluation of electronic structure, captures both mode distortion and Duschinsky rotation. We apply the method to compute SVL spectra of anthracene by performing wavepacket dynamics on a 66- dimensional harmonic potential energy surface constructed from density functional theory calculations. With the Hagedorn approach, we not only reproduce the previously reported simulation results for singly excited $12^{1}$ and $\overline{11}^{1}$ levels, but also are able to compute SVL spectra from multiply excited levels in good agreement with experiments. All spectra were obtained from the same wavepacket trajectory without any additional propagation beyond what is required for ground-state emission spectra.

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