Vibronic structure and predissociation dynamics of 2-methoxythiophenol (S): The effect of intramolecular hydrogen bonding on nonadiabatic dynamics.

Vibronic spectroscopy and the S-H bond predissociation dynamics of 2-methoxythiophenol (2-MTP) in the S (ππ) state have been investigated for the first time. Resonant two-photon ionization and slow-electron velocity map imaging (SEVI) spectroscopies have revealed that the S-S transition of 2-MTP is accompanied with the planar to the pseudoplanar structural change along the out-of-plane ring distortion and the tilt of the methoxy moiety. The S vibronic bands up to their internal energy of ∼1000 cm are assigned from the SEVI spectra taken via various S vibronic intermediate states with the aid of ab initio calculations. Intriguingly, Fermi resonances have been identified for some vibronic bands. The S-H bond breakage of 2-MTP occurs via tunneling through an adiabatic barrier under the S/S conical intersection seam, and it is followed by the bifurcation into either the adiabatic or nonadiabatic channel at the S/S conical intersection where the diabatic S state (πσ) is unbound with respect to the S-H bond elongation coordinate, giving the excited (Ã) or ground (X̃) state of the 2-methoxythiophenoxy radical, respectively. Surprisingly, the nonadiabatic transition probability at the S/S conical intersection, estimated from the velocity map ion images of the nascent D fragment from 2-MTP-d (2-CHO-CHSD) at the S zero-point energy level, is found to be exceptionally high to give the X̃/Ã product branching ratio of 2.03 ± 0.20, which is much higher than the value of ∼0.8 estimated for the bare thiophenol at the S origin. It even increases to 2.33 ± 0.17 at the ν mode (101 cm) before it rapidly decays to 0.69 ± 0.05 at the S internal energy of about 2200 cm. This suggests that the strong intramolecular hydrogen bonding of S⋯D⋯OCH in 2-MTP at least in the low S internal energy region should play a significant role in localizing the reactive flux onto the conical intersection seam. The minimum energy pathway calculations (second-order coupled-cluster resolution of the identity or time-dependent-density functional theory) of the adiabatic S state suggest that the intimate dynamic interplay between the S-H bond cleavage and intramolecular hydrogen bonding could be crucial in the nonadiabatic surface hopping dynamics taking place at the conical intersection.