1. Kronholm D. F. et al. Blends of fullerene derivatives, and uses thereof in electronic devices. Patent №: US 8,945,807 B2, date of Patent: Feb. 3, 2015., D. F. Kronholm et al., Blends of fullerene derivatives, and uses thereof in electronic devices. Patent №: US 8,945,807 B2, date of Patent : Feb. 3, 2015.
2. Bakhramov S. A.; Kokhkharov A. M.; Makhmanov U. K.; Aslonov B. A. Self-Organization of Fullerene C60/70 Molecules in Solutions and in the Volume of Drying Drop // Scientific-technical journal. 2020. Vol. 24, iss. 5. Article 6., S. A. Bakhramov, A. M. Kokhkharov, U. K. Makhmanov, and B. A. Aslonov, “Self-Organization of Fullerene C60/70 Molecules in Solutions and in the Volume of Drying Drop,” Scientific-technical journal, vol. 24, iss. 5, Article 6, 2020.
3. Harris P. J. F. Fullerene Polymers : A Brief Review // Journal of Carbon Research. 2020. Т. 6, № 4. С. 71., P. J. F. Harris, “Fullerene Polymers : A Brief Review,” Journal of Carbon Research, vol. 6, no. 4, p. 71, Nov. 2020, doi: 10.3390/c6040071.
4. Evstigneev M. P. et al. Complexation of C60 fullerene with aromatic drugs // Chem-PhysChem. 2013. Т. 14, № 3. С. 568—578., M. P. Evstigneev, A. S. Buchelnikov, D. P. Voronin, Y. V. Rubin, L. F. Belous, Y. I. Prylutskyy, U. Ritter, “Complexation of C60 fullerene with aromatic drugs,” ChemPhysChem, vol 14, no. 3, pp. 568–578, 2013.
5. Prylutska S. et al. Water-Soluble Pristine Fullerenes C60 Increase the Specific Conductivity and Capacity of Lipid Model Membrane and form the Channels in Cellular Plasma Membrane // J. Biomed. Nanotechnol. 2012. Т. 8, № 3. С. 522—527., S. Prylutska et al., “Water-Soluble Pristine Fullerenes C60 Increase the Specific Conductivity and Capacity of Lipid Model Membrane and form the Channels in Cellular Plasma Membrane,” J. Biomed. Nanotechnol., vol. 8, no. 3, pp. 522–527, Jun. 2012, doi: 10.1166/jbn.2012.1404.