Vibrational Circular Dichroism and Theoretical Study of the Conformational Equilibrium in (−)-S-Nicotine

We report an extensive study of the molecular and electronic structure of (−)‐S‐nicotine, to deduce the phenomenon that controls its conformational equilibrium and to solve its solution‐state conformer population. Density functional theory, ab initio, and molecular mechanics calculations were used together with vibrational circular dichroism (VCD) and Fourier transform infrared spectroscopies. Calculations and experiments in solution show that the structure and the conformational energy profile of (−)‐S‐nicotine are not strongly dependent on the medium, thus suggesting that the conformational equilibrium is dominated by hyperconjugative interactions rather than repulsive electronic effects. The analysis of the first recorded VCD spectra of (−)‐S‐nicotine confirmed the presence of two main conformers at room temperature. Our results provide further evidence of the hypersensitivity of vibrational optical activity spectroscopies to the three‐dimensional structure of chiral samples and prove their suitability for the elucidation of solution‐state conformer distribution. Smoke screen: Vibrational circular dichroism spectroscopy confirms the incidence of a conformational mixture (2:1 m01/m02; see figure) in (−)‐S‐nicotine (pure liquid and DMSO and CCl4 solutions). Experimental and theoretical results indicate that hyperconjugative interactions play a dominant role in the conformational equilibrium.