RESUMO
The solvent-dependent excited state behavior of the molecular push-pull system 2-diethylamino-7-nitrofluorene has been explored using femtosecond transient absorption spectroscopy in combination with density functional theory calculations. Several excited state minima have been identified computationally, all possessing significant intramolecular charge transfer character. The experimentally observed dual fluorescence is suggested to arise from a planar excited state minimum and another minimum reached by twisting of the aryl-nitrogen bond of the amino group. The majority of the excited state population, however, undergo non-radiative transitions and potential excited state deactivation pathways are assessed in the computational investigation. A third excited state conformer, characterized by twisting around the aryl-nitrogen bond of the nitro group, is reasoned to be responsible for the majority of the non-radiative decays and a crossing between the excited state and ground state is localized. Additionally, ultrafast intersystem crossing is observed in the apolar solvent cyclohexane and rationalized to occur via an El-Sayed assisted transition from one of the identified excited state minima. The solvent thus determines more than just the fluorescence lifetime and shapes the potential energy landscape, thereby dictating the available excited state pathways.
RESUMO
The photoinduced processes of methyl formate and methyl acetate have been probed by femtosecond time-resolved mass spectrometry and photoelectron spectroscopy experiments supported by quantum chemical calculations. Upon excitation to a vibrationally hot S1 state both molecules were found to relax away from the Franck-Condon geometry faster than the cross-correlation (≈170 fs). During relaxation of the S1 surface intersystem crossing to the triplet manifold is possible via the T2 state which enables an El-Sayed allowed transition. The time-resolved photoelectron spectra show indications of a triplet state formed on an ultrafast timescale. We suggest that the ultrafast timescale of the intersystem crossing process is possible due to the shape of the potential energy surface directing and restricting the dynamics along the carbonyl group de-planarization coordinate, where an El-Sayed allowed intersystem crossing is possible at all times, and where the S1 and T2 states are nearly iso-energetic all the way along the reaction coordinate.