Infrared spectroscopy of small-molecule endofullerenes

Abstract

Hydrogen is one of the few molecules which has been incarcerated in the molecular cage of C60 and forms endohedral supramolecular complex H2@C60. In this confinement hydrogen acquires new properties. Its translational motion becomes quantized and is correlated with its rotations. We applied infrared spectroscopy to study the dynamics of hydrogen isotopologs H2, D2 and HD incarcerated in C60. The translational and rotational modes appear as side bands to the hydrogen vibrational mode in the mid infrared part of the absorption spectrum. Because of the large mass difference of hydrogen and C60 and the high symmetry of C60 the problem is identical to a problem of a vibrating rotor moving in a three-dimensional spherical potential. The translational motion within the C60 cavity breaks the inversion symmetry and induces optical activity of H2. We derive potential, rotational, vibrational and dipole moment parameters from the analysis of the infrared absorption spectra. Our results were used to derive the parameters of a pairwise additive five-dimensional potential energy surface for H2@C60. The same parameters were used to predict H2 energies inside C70[Xu et al., J. Chem. Phys., 130, 224306 (2009)]. We compare the predicted energies and the low temperature infrared absorption spectra of H2@C70.