Molecules (Feb 2023)

Structure and Vibrational Spectroscopy of C<sub>82</sub> Fullerenol Valent Isomers: An Experimental and Theoretical Joint Study

  • Felix N. Tomilin,
  • Polina V. Artyushenko,
  • Irina A. Shchugoreva,
  • Anastasia V. Rogova,
  • Natalia G. Vnukova,
  • Grigory N. Churilov,
  • Nikolay P. Shestakov,
  • Olga N. Tchaikovskaya,
  • Sergei G. Ovchinnikov,
  • Pavel V. Avramov

DOI
https://doi.org/10.3390/molecules28041569
Journal volume & issue
Vol. 28, no. 4
p. 1569

Abstract

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Gd@C82OxHy endohedral complexes for advanced biomedical applications (computer tomography, cancer treatment, etc.) were synthesized using high-frequency arc plasma discharge through a mixture of graphite and Gd2O3 oxide. The Gd@C82 endohedral complex was isolated by high-efficiency liquid chromatography and consequently oxidized with the formation of a family of Gd endohedral fullerenols with gross formula Gd@C82O8(OH)20. Fourier-transformed infrared (FTIR) spectroscopy was used to study the structure and spectroscopic properties of the complexes in combination with the DFTB3 electronic structure calculations and infrared spectra simulations. It was shown that the main IR spectral features are formed by a fullerenole C82 cage that allows one to consider the force constants at the DFTB3 level of theory without consideration of gadolinium endohedral ions inside the carbon cage. Based on the comparison of experimental FTIR and theoretical DFTB3 IR spectra, it was found that oxidation of the C82 cage causes the formation of Gd@C82O28H20, with a breakdown of the integrity of the parent C82 cage with the formation of pores between neighboring carbonyl and carboxyl groups. The Gd@C82O6(OOH)2(OH)18 endohedral complex with epoxy, carbonyl and carboxyl groups was considered the most reliable fullerenole structural model.

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