METANDAN MEZOG’OVAKLI UGLEROD OLISH REAKSIYASI TEZLIGIGA TURLI OMILLARNING TA’SIRI
Keywords:
methane,, catalyst, nanocarbonAbstract
. The rate of formation of nanocarbon layers in the presence of 15%Ni*5%Co*5%Fe*5%Cu/YuKS and 15%Ni*5%Co*5%Fe*5%Cu*2%Mo/YuKS catalysts the effect of different parameters of catalytic pyrolysis of methane (catalyst layer thickness, gas phase movement speed, process temperatures) was studied.
References
Баннов А. Г., Кувшинов Г. Г. // Материаловедение. 2011. Но 10. C. 47.
Крутский Ю. Л., Баннов А. Г., Соколов В. В. и др. // Рос. нанотехнологии. 2013. Но 3-4. С. 22
Решетенко Т. В., Авдеева Л. Б., Исмагилов З. Р. ет ал. // Апплиед Cаталйсис А: Генерал 2003. Вол. 247. П. 51.
Кувшинов Г. Г., Чуканов И. С., Круцкй Й. Л. ет ал. // Cарбон. 2009. Вол. 47. Р. 215.
Handbook of Nanophysics. Clusters and Fullerenes, edited by Klaus D. Sattler (CRC Press, Taylor and Francis Group, LLC, 2010).
R. Sure, R. Tonner, P. Schwerdtfeger, A systematic study of rare gas atoms encapsulated in small fullerenes using dispersion corrected density functional theory // J. Comp. Chem. 36 (2015) 88.
P.W. Dunk, H. Niwa, H. Shinohara, A.G. Marshall, H.W. Kroto, Large fullerenes in mass spectra // Mol. Phys. 113 (2015) 2359.
Y. Jin, A. Perera, V.F. Lotrich, R.J. Bartlett, Couple cluster geometries and energies of C20 carbon cluster isomers // Chem. Phys. Lett. 629 (2015) 76.
Iijima, S. Helical microtubules of graphitic carbon.Nature1991,354, 56–58.
Iijima, S.; Ichihashi, T. Single-shell carbon nanotubes of 1-nm diameter.Nature1993,363, 603–605.
Kroto, H.W.; Heath, J.R.; Obrien, S.C.; Curl, R.F.; Smalley, R.E. C60: Buckminsterfullerene.Nature1985,318,162–163.
Bobomurodova, S.Y., Fayzullaev, N.I., Usmanova, K.A. Catalytic aromatization of oil satellite gases//International Journal of Advanced Science and Technology, 2020, 29(5), стр. 3031–3039.
Tursunova, N.S., Fayzullaev, N.I. Kinetics of the reaction of oxidative dimerization of methane//International Journal of Control and Automation, 2020, 13(2), стр. 440–446
Fayzullaev, N.I., Bobomurodova, S.Y., Catalytic change of C1-C4-alkanes// International Journal of Control and Automation, 2020, 13(2), стр. 827–835
Fayzullaev, N.I, Bobomurodova, S.Y, Xolmuminova, D.A Physico-chemical and texture characteristics of Zn-Zr/VKTS catalyst//Journal of Critical Reviews, 2020, 7(7), стр. 917–920
Aslanov, S.C., Buxorov, A.Q., Fayzullayev, N.I. Catalytic synthesis of С2-С4-alkenes from dimethyl ether// International Journal of Engineering Trends and Technology, 2021, 69(4), стр. 67–75.
F N Temirov, J Kh Khamroyev, N I Fayzullayev, G Sh Haydarov and M Kh Jalilov. Hydrothermal synthesis of zeolite HSZ-30 based on kaolin// IOP Conf. Series: Earth and Environmental Science 839 (2021) 042099. IOP Publishing doi:10.1088/1755-1315/839/4/042099
Berdimurodov, E., Kholikov, A., Akbarov, K., Guo, L., Umirov, N., Verma, D. K., ... & Kaya, S. (2022). Ionic liquids as green and sustainable corrosion inhibitors I. In Eco-Friendly Corrosion Inhibitors (pp. 331-390). Elsevier.
Berdimurodov, E., Kholikov, A., Akbarov, K., El Ibrahimi, B., Verma, D. K., Berdimuradov, K., ... & Umirov, N. (2023). Advanced fiber materials in pollution control. Fiber Materials: Design, Fabrication and Applications, 89
Berdimurodov, E., Verma, C., Berdimuradov, K., Quraishi, M. A., Kholikov, A., Akbarov, K., ... & Borikhonov, B. (2022). 8–Hydroxyquinoline is key to the development of corrosion inhibitors: An advanced review. Inorganic Chemistry Communications, 109839.
