Study of Thermolysis of Hydrogenated Carbon Molecules as Products of Fullerenization of Benzene, Xylene, Ethanol and Pyridine

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Author(s) 

Alexey I. Kharlamov¹, Marina E. Bondarenko^1*, Ganna A. Kharlamova², Boris B. Palyanitsa³, Yury A. Zagorodny¹

 

Affiliation(s)

¹Frantsevich Institute for Problems of Materials Science of NASU, Kiev, Ukraine.
²Taras Shevchenko National University of Kiev, Kiev, Ukraine.
³O. O. Chuiko Institute of Surface Chemistry, NAS of Ukraine, Kiev, Ukraine.

ABSTRACT

Novel essentially distinct from already known (methods of hydrogenation of fullerenes (C60 and C70) or fullerite) method for the synthesis of highly hydrogenated carbon molecules is developed; such approach is perspective hydrogen capacity accumulators. First, the reactionary conditions are created for the realization of the process of fullerenization as direct transformation of molecules of aromatic hydrocarbons, pyridine and ethanol into carbon molecules, fulleranes (С60Н8-С60Н60 and С70Н8-С70Н44) and quasi-fulleranes (CnHn-6-CnHn-2 (n = 20 - 46)) containing up to 5.7 wt% hydrogen. X-ray amorphous powders of hydrogenated carbon molecules in gram amounts are obtained. Appreciable dehydrogenation of such samples of fulleranes and quasi-fulleranes at ~50°C is began, while dehydrogenation of synthesized from fullerene (or fullerite) fulleranes is observed only at temperatures above 400°C. Methods of NMR, IR spectroscopy, mass spectrometry MALDI and temperature-programmed desorption mass spectrometry EI are used for the study of condensed products of fullerenization of precursors molecules.

 

KEYWORDS

Fullerenization, Fulleranes, Quasi-Fulleranes, Carbon Molecules, Pyrolysis, Fullerenes, Dehydrogenation

Cite this paper

Kharlamov, A. , Bondarenko, M. , Kharlamova, G. , Palyanitsa, B. and Zagorodny, Y. (2015) Study of Thermolysis of Hydrogenated Carbon Molecules as Products of Fullerenization of Benzene, Xylene, Ethanol and Pyridine. Open Journal of Synthesis Theory and Applications, 4, 22-32. doi: 10.4236/ojsta.2015.41003.

 

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