A Facile Route to the Non‐IPR Fullerene Sc3N@C68: Synthesis, Spectroscopic Characterization, and Density Functional Theory Computations (IPR=Isolated Pentagon Rule)

Abstract

Owing to the unique feature of the non-IPR D₃ (isomer 6140) C₆₈ cage (IPR=isolated pentagon rule), Sc₃N@C₆₈ has been attracting great interest in the fullerene community. Herein we report the first high-yield synthesis of Sc₃N@C₆₈ by the “reactive gas atmosphere” method and its facile isolation by single-step HPLC to a high purity (≥99 %). Thus, Sc₃N@C₆₈ is isolated in sufficient quantities for its further spectroscopic characterization, while the high purity of the sample ensures the reliability of the spectroscopic data obtained. In particular, the electronic and vibrational structures of Sc₃N@C₆₈ were studied in detail experimentally and by theoretical computations. The assignment of the observed absorption bands to particular electronic transitions is given in detail on the basis of time-dependent DFT computations. Vibrational spectroscopy of Sc₃N@C₆₈ reveals good agreement between the measured spectra and the theoretically calculated spectra. A detailed assignment of the vibrational modes, including the Sc₃N cluster modes, cage modes, and vibrations of the adjacent pentagons are discussed. This study reveals that the effect of Sc₃N encapsulation in the cage is much more complicated than just a formal transfer of six electrons. Consequently the electronic and vibrational spectra of the carbon cage in Sc₃N@C₆₈ cannot be adequately understood on the basis of a C₆₈⁶⁻ cage alone.