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Общий стаж работы 44 года (с 01.09.1979)
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Electroflotation recovery of highly dispersed carbon materials from aqueous solutions of electrolyte / A. V. Kolesnikov, A. D. Milyutina, A. V. Desyatov, V. A. Kolesnikov // Separation and Purification Technology. — 2019. — Vol. 209. — P. 73–78. Physicochemical characteristics (specific surface area of the material, particle size, particle charge, functional groups on the surface of the material, critical micelle concentration) of highly dispersed carbon materials in aqueous solutions in the presence of surfactants of different nature were studied experimentally. The influence of these characteristics on the electroflotation process of carbon nanoflakes was shown. Also, the influence of various additives (electrolytes, flocculants, coagulants) on the process of electroflotation extraction of carbon nanoflakes and activated carbon of brand OU-B from aqueous solutions was studied. [ DOI ]

Nanomaterials for electrical energy storage. ‒ chapter 5.07 / A. B. Yaroslavtsev, I. A. Stenina, M. T. L. Kulova Alexander Skundin, A. V. Desyatov // Comprehensive Nanoscience and Nanotechnology, 2nd Edition, Editor-in-Chiefs: David Andrews, Thomas Nann, Robert Lipson,. — Vol. 5. — Elsevier, Academic Pres, 2019. — P. 165–206. [ DOI ]

Nanomaterials for electrical energy storage. ‒ chapter 5.07 in editor-in-chiefs: David andrews, thomas nann, robert lipson, elsevier, academic press, p. 165‒206 / A. B. Yaroslavtsev, I. A. Stenina, T. L. Kulova et al. // Comprehensive Nanoscience and Nanotechnology, 2nd Edition,. — Elsevier, Academic Press, 2019. — P. 165–206.

Structure and properties of new dicationic ionic liquid dbtmeda(bf4)2 / M. A. Zakharov, A. S. Ivanov, E. A. Arkhipova et al. // Structural Chemistry. — 2019. — Vol. 30, no. 2. — P. 451–456. Abstract Dicationic ionic liquid (IL) dibutyltetramethylethylenediammonium tetrafluoridoborate was synthesized for the first time by quaternization followed by ion exchange. The chemical composition was confirmed by 1H, 19F, and 13C nuclear magnetic resonance (NMR) spectroscopy. The crystal structure of the IL under discussion was determined from single crystal diffraction and can be described in monoclinic syngony with P21/c space group. Using thermal analysis and mass spectrometry, thermal stability of this IL as well as possible directions of its destruction was analyzed. Melting point for this liquid was determined by simultaneous thermal analysis as 135 oC. The electrochemical stability range for this ionic liquid was find to be nearly symmetrical accordingly to cyclic voltammetry and estimated as 3.75 V. Keywords Ionic liquids . Thermal analysis . Crystal structure . NMR spectroscopy . Electrochemical window . Conductivity. [ DOI ]

Increasing the efficiency of the electroflotation recovery of finely dispersed carbon material in the presence of surfactants from liquid technogenic waste / V. A. Kolesnikov, A. V. Desyatov, A. D. Milyutina, A. V. Kolesnikov and // Theoretical Foundations of Chemical Engineering. — 2018. — Vol. 52, no. 1. — P. 67–73. The electroflotation recovery of a finely dispersed carbon material, namely, carbon nanoflakes, from aqueous solutions in the pH range of 3.0–11.0 in the presence of different forms of surfactants has been experimentally studied. The electroflotation of carbon nanoflakes from aqueous solutions with the addition of the FeCl3 coagulant has been investigated. The experimental dependences of the degree of recovery and the electrokinetic potential on the pH value of the medium in the presence and absence of a coagulating agent have been derived. The optimal values of characteristics such as the pH value of the medium, volumetric current density, electroflotation time, and the initial concentrations of Fe3+ ions and surfactants for effective electroflotation of carbon nanoflakes have been found.