High-Resolution Electronic Spectroscopy of the Doorway
States to Intramolecular Charge Transfer
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Abstract
Reported here are several of the ground, first, and second excited
state structures and dipole moments of three benchmark intramolecular
charge transfer (ICT) systems; 4-(1<i>H</i>-pyrrol-1-yl)benzonitrile
(PBN), 4,4′-dimethylaminobenzonitrile (DMABN), and 4-(1-pyrrolidinyl)benzonitrile
(PYRBN), isolated in the gas phase and probed by rotationally resolved
spectroscopy in a molecular beam. The related molecules 1-phenylpyrrole
(PP) and 4-aminobenzonitrile (ABN) also are discussed. We find that
the S<sub>1</sub> electronic state is of B symmetry in all five molecules.
In PBN, a second excited state (S<sub>2</sub>) of A symmetry is found
only ∼400 cm<sup>–1</sup> above the presumed origin
of the S<sub>1</sub> state. The change in dipole moment upon excitation
to the A state is measured to be Δμ ≈ 3.0 D, significantly
smaller than the value predicted by theory and also smaller than that
observed for the “anomalous” ICT band of PBN in solution.
The B state dipole moments of DMABN and PYRBN are large, ∼10.6
D, slightly larger than those attributed to “normal”
LE fluorescence in solution. In addition, we find the unsaturated
donor molecules (PP, PBN) to be twisted in their ground states and
to become more planar upon excitation, even in the A state, whereas
the saturated donor molecules (ABN, DMABN, PYRBN), initially planar,
either remain planar or become more twisted in their excited states.
It thus appears that the model that is appropriate for describing
ICT in these systems depends on the geometry of the ground state