Abstract
Low-lying singlet excited states of pyrene derivatives originated from the 1La and 1Lb states of pyrene have decisive influences on their absorption and fluorescence emission behaviors. Calculation of these excited states with quantitative accuracy is required for the theoretical design of pyrene derivatives tailored to target applications; this has been a long-standing challenge for ab initio quantum chemical calculations. In this study, we explore an adequate computational scheme through calculations of pyrene and its phenyl-substituted derivatives using multi-reference perturbation theory (MRPT) methods. All valence π orbitals on the pyrene moiety were assigned to the active orbitals. Computational load was reduced by restricting the electron excitations within the active orbitals in the preparation of reference configuration space. A generalized multi-configuration quasi-degenerate perturbation theory (GMCQDPT) was adopted to treat the reference space other than the complete active space. The calculated 1La and 1Lb excitation energies of pyrene are in good agreement with the experimental values. Calculations of 1,3,6,8-tetraphenyl pyrene suggest that the energetic ordering of 1La and 1Lb is inverted through tetraphenyl substitution and its lowest singlet excited state is the 1La parentage of pyrene, which is consistent with the experimentally deduced scheme. These results are not readily obtained by MRPT calculations with a limited number of active orbitals and single-reference theory calculations. Diphenyl pyrenes (DPPy) were also calculated at the same level of theory to investigate the dependence on the substitution positions of phenyl groups.
Highlights
Pyrene is one of the most well-studied polycyclic aromatic hydrocarbons (PAHs) because of its characteristic photophysical properties, such as prominent absorption bands and a uorescence emission.[1]
We explore an adequate computational scheme that is suitable for the excited states of pyrene derivatives
HOMOÀ1 / lowest unoccupied molecular orbital (LUMO) and highest occupied molecular orbital (HOMO) / LUMO+1 single excitations are dominant in the 1Lb state.[119,129]
Summary
Pyrene is one of the most well-studied polycyclic aromatic hydrocarbons (PAHs) because of its characteristic photophysical properties, such as prominent absorption bands and a uorescence emission.[1]. Excitation from the ground state to the 1La state gives a prominent absorption band around 340 nm in the UV/Vis spectrum because of its large oscillator strength. The oscillator strength of the 1Lb state is negligibly small; the 1Lb absorption band is barely visible in the absorption spectrum.[66] The 1Lb state is the lowest singlet excited state and the 1La state is the second lowest; the uorescence emission of pyrene is of 1Lb parentage according to Kasha's rule.[67] In substituted pyrene derivatives, the excitation energies and absorbance of these excited states are perturbed by the substituents. Even an energetic ordering of the 1La and 1Lb states is inverted
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