Excitonic Splitting and Vibronic Coupling Analysis of the m-Cyanophenol Dimer

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• 作者：Franziska A. Balmer ; Sabine Kopec ; Horst Köppel ; Samuel Leutwyler
• 刊名：Journal of Physical Chemistry A
• 出版年：2017
• 出版时间：January 12, 2017
• 年：2017
• 卷：121
• 期：1
• 页码：73-87
• 全文大小：737K
• ISSN：1520-5215

文摘

The S₁/S₂ splitting of the m-cyanophenol dimer, (mCP)₂ and the delocalization of its excitonically coupled S₁/S₂ states are investigated by mass-selective two-color resonant two-photon ionization and dispersed fluorescence spectroscopy, complemented by a theoretical vibronic coupling analysis based on correlated ab initio calculations at the approximate coupled cluster CC2 and SCS-CC2 levels. The calculations predict three close-lying ground-state minima of (mCP)₂: The lowest is slightly Z-shaped (C_i-symmetric); the second-lowest is <5 cm^–1 higher and planar (C_2h). The vibrational ground state is probably delocalized over both minima. The S₀ → S₁ transition of (mCP)₂ is electric-dipole allowed (A_g → A_u), while the S₀ → S₂ transition is forbidden (A_g → A_g). Breaking the inversion symmetry by ¹²C/¹³C- or H/D-substitution renders the S₀ → S₂ transition partially allowed; the excitonic contribution to the S₁/S₂ splitting is Δ_exc = 7.3 cm^–1. Additional isotope-dependent contributions arise from the changes of the m-cyanophenol zero-point vibrational energy upon electronic excitation, which are Δ_iso(¹²C/¹³C) = 3.3 cm^–1 and Δ_iso(H/D) = 6.8 cm^–1. Only partial localization of the exciton occurs in the ¹²C/¹³C and H/D substituted heterodimers. The SCS-CC2 calculated excitonic splitting is Δ_el = 179 cm^–1; when multiplying this with the vibronic quenching factor Γ_vibron^exp = 0.043, we obtain an exciton splitting Δ_vibron^exp = 7.7 cm^–1, which agrees very well with the experimental Δ_exc = 7.3 cm^–1. The semiclassical exciton hopping times range from 3.2 ps in (mCP)₂ to 5.7 ps in the heterodimer (mCP-h)·(mCP-d). A multimode vibronic coupling analysis is performed encompassing all the vibronic levels of the coupled S₁/S₂ states from the v = 0 level to 600 cm^–1 above. Both linear and quadratic vibronic coupling schemes were investigated to simulate the S₀ → S₁/S₂ vibronic spectra; those calculated with the latter scheme agree better with experiment.