We propose a classification of individual nanoparticles on the basis of the form of the surface and the internal architectural packing for investigations carried out with the help of transmission electron microscopy. The investigated samples contain individual nanoparticles of seven kinds in different ratios: rounded, tubular, fibrous, fi lm, "veil," "active" particles and "particles with regular geometric contours." The classification was made on the basis of an analysis of the results of investigations of the surfaces and internal architectural packing of carbon particles obtained in different physiochemical processes (carbonization, carburizing, arc discharge, mechanochemical treatment, plasma chemistry, and in carbon-containing fl ames). For the source materials, we used waste of farming products and widely distributed mineral raw materials.
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References
I. P. Suzdalev, Nanotechnology. Physicochemistry Chemistry of Nanoclusters, Nanostructures, and Nanomaterials [in Russian], KomKniga, Moscow (2005).
Peter J. F. Harris, Carbon Nanotubes and Related Structures. New Materials for the Twenty-First Century, Cambridge University Press, London (2000).
R. M. Mansurova, Carbon-Containing Composites. Present-Day Problems. Chemistry, Chemical Technology [in Russian], KazNU, Almaty (2001).
B. M. Baloyan, A. G. Kolmakov, M. I. Alymov, and A. M. Krotov, Nanomaterials: Classifi cation, Characteristic Features, Application, and Production Technology [in Russian], "Dubna"–"Ugresh," Moscow (2007).
E. A. Belenkov, Classifi cation of carbon structures, in: 8th Int. Conf. ICHMS-2003 "Hydrogen Materials Science & Chemistry of Carbon Nanomaterials," 14–20 September 2003, Sudak (2003), pp. 732–736.
A . Burian, J. C. Dore, and H. E. Fisher, Structural studies of multiwall carbon nanotubes by neutron diffraction, Phys. Rev. B, 59, 1665–1667 (1999).
T. A. Shabanova, V. I. Antonyuk, O. V. Zashkvara, Yu. A. Ryabikin, and R. M. Mansurova, Study of the structure of the carbonaceous substance of sorbents by the methods of electronic microscopy, XPhA- and EPR spectroscopy, Vestn. KazNU, Ser. Khim., 36, No. 4, 462–466 (2004).
M. Damnjanovic, T. Milosevic, and I. Vukovic, Full symmetry, optical activity, and potentials of single-wall and multiwall nanotubes, Phys. Rev. B, 60, 2728–2729 (1999).
N. N. Mofa, V. I. Antonyuk, T. A. Shabanova, B. S. Sadykov, Z. A. Mansurov, and S. Kh. Aknazarov, Mechanochemical modifi cation as an effi cient method of creating nanolayered structures on the particle surface. 1. Modifi cation of quartz, Goren. Plazmokhim., 8, No. 2, 139–146 (2010).
N. N. Mofa, R. G. Abdulkarimova, A. V. Mironenko, T. A. Shabanova, G. K. Eszhanova, and Z. A. Mansurov, Synthesis of nanostructured composite materials in the regime of fi ltration combustion of preliminarily activated and modifi ed systems, in: Proc. 5th Int. Symp. "Physics and Chemistry of Carbon Materials. Nanoengineering," 10–12 September 2008, KazNU, Almaty (2008), pp. 81–85.
V. E. Messerle, V. G. Luk'yashchenko, and A. B. Ustimenko, Plasma pyrolysis of a propane–butane gaseous mixture for obtaining hydrogen and technical carbon, in: Proc. 5th Int. Symp. "Combustion and Plasma Chemistry," 16–18 September 2009, KazNU, Almaty (2009), pp. 123–127.
T. A. Shabanova, Morphostructure
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Translated from Inzhenerno-Fizicheskii Zhurnal, Vol. 87, No. 5, pp. 1190–1198, September–October, 2014.
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Mansurov, Z.A., Shabanova, T.A., Mofa, N.N. et al. Carbon Nanomaterials: Surface Structure and Morphology. J Eng Phys Thermophy 87, 1241–1248 (2014). https://doi.org/10.1007/s10891-014-1126-x
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DOI: https://doi.org/10.1007/s10891-014-1126-x