4.7 Article

Internal dynamics of methyl p-tolyl sulfoxide in the gas phase: Rotational spectroscopy and theoretical studies

Journal

JOURNAL OF CHEMICAL PHYSICS
Volume 156, Issue 15, Pages -

Publisher

AIP Publishing
DOI: 10.1063/5.0083534

Keywords

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Funding

  1. Deutsche Forschungsgemeinschaft [SFB 1319]
  2. European XFEL

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In this study, the pure rotational spectrum of methyl p-tolyl sulfoxide (MTSO) was investigated, and a single conformer was observed. The molecular geometry and internal rotation mechanism were determined using quantum-chemical calculations and isotopic substitution experiments. Additionally, the pyramidal inversion at the sulfur stereogenic center was explored, and it was found that optical excitation to the excited state facilitates barrier-free inversion.
A pure rotational spectrum of methyl p-tolyl sulfoxide (MTSO) was studied using chirped-pulse Fourier transform microwave spectroscopy in the frequency range of 18-26 GHz. A single conformer was unambiguously observed in the supersonic jet expansion, which is consistent with the conformational analysis performed using quantum-chemical calculations. Rotational transitions were split into two components of A and E symmetries due to the low-barrier internal rotation of the ring methyl group [V-3 = 11.0178(23) cm(-1)]. The low energy barrier for the methyl top internal rotation implies an electron-withdrawing effect of the group at the opposite side of the phenyl ring, in comparison with other para-substituted toluenes. The effective ground state (r(0)) geometry was derived using the rotational constants from the parent species and the S-34 and eight C-13 singly substituted isotopologues. Compared to two other sulfoxides, methyl phenyl sulfoxide and methyl 4-nitrophenyl sulfoxide, the sulfoxide group in MTSO is slightly more twisted with respect to the plane of the phenyl ring, which could be attributed to the moderate electron-donating effect of the p-methyl group. Furthermore, the pyramidal inversion that interconverts the handedness at the sulfur stereogenic center was explored in the electronic ground (S-0) and excited (S-1) states with nudged elastic band and time-dependent density functional theory methods. It was found that the pyramidal inversion in S-1 is easier than in S-0, showing that optical excitation to S-1 will facilitate an effectively barrier-free inversion. (C) 2022 Author(s).

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