Abstract

The inelastic-neutron-scattering spectra in the 500-\ensuremath{\mu}eV region of a series of mixtures of totally hydrogenated and totally deuterated 4-methyl-pyridine molecules (4MP-${\mathit{h}}_{7}$ and 4MP-${\mathit{d}}_{7}$, respectively) with relative concentrations in 4MP-${\mathit{h}}_{7}$ of 100, 85, 65, 50, 26, 20, and 5 % are presented at various temperatures: 2.5, 4.5, 6.5, 8.5, 11 and 15 K. In pure 4MP-${\mathit{h}}_{7}$ at 2.5 K, the spectrum shows three partially resolved bands at 468, 510, and 535 \ensuremath{\mu}eV. These frequencies are unaffected by temperature up to 15 K where the bands become rather weak. At 2.5 K, the main peak shows a continuous frequency shift with increasing concentration in 4MP-${\mathit{d}}_{7}$ down to 360 \ensuremath{\mu}eV (5% 4MP-${\mathit{h}}_{7}$) indicating collective motions of the methyl groups. This frequency shift is very sensitive to temperature and vanishes above 10 K. These unusual aspects of the methyl-group dynamics are quantitatively represented by the quantum sine-Gordon equation describing a one-dimensional infinite chain of coupled methyl groups. Accordingly, the weak side bands at 468 and 535 \ensuremath{\mu}eV are assigned to in-phase and out-of-phase tunneling transitions, respectively. The main peak at 510 \ensuremath{\mu}eV in pure 4MP-${\mathit{h}}_{7}$ is due to the excitation of the first quantized traveling state of the breather mode. Isotopic dilution effects are understood in terms of breathers trapped in clusters of 4MP-${\mathit{h}}_{7}$ molecules surrounded by 4MP-${\mathit{d}}_{7}$ molecules which act as reflective walls. Temperature effects are due to the thermal excitation of breather-roton states in relationship with the zero-point energy difference for 4MP-${\mathit{h}}_{7}$ and 4MP-${\mathit{d}}_{7}$ clusters. Finally, some previous spectroscopic data are reconsidered on the basis of the quantum sine-Gordon theory.