• Покупка статей
  • Telegram_OreMet
Скрыть
Журналы →  Materialy Elektronnoi Tekhniki →  2013 →  №1 →  Назад

NANOMATERIALS AND NANOTECHNOLOGY
Название Formation of Nanocomposites Ni/C Based of Polyacrylonitrile Under IR−radiation
Автор D. G. Muratov, E. V. Yakushko, L. V. Kozhitov, A. V. Popkova, M. A. Pushkarev
Информация об авторе

A. V. Topchiev Institute of Petrochemical Synthesis, RAS

D. G. Muratov, L. V. Kozhitov

 

University of Science and Technology MISiS

E. V. Yakushko, A. V. Popkova, M. A. Pushkarev
Реферат

The work is dedicated to obtaining nickel metal−carbon nanocomposites, based on IR−pyrolyzed polyacrylonitrile and nickel chloride hexahydrate, and the study of the structural characteristics of the synthesized material. Nanocomposites prepared under IR−based precursor pyrolysis of polyacrylonitrile (PAN) and nickel chloride hexahydrate (NiCl2 · 6H2O). Pyrolysis was carried out in the temperature range 150—700 °C. The grown nanocomposites are two−phase system of the carbon matrix formed during carbonization of PAN, and distributed in the nanoparticles of nickel (nickel oxide). The average size of the nanoparticles in the nanocomposite was 15—25 nm. The effect of temperature pyrolysis process IR precursor in the size of nickel nanoparticles obtained. It was determined that the distribution of nickel nanoparticles in size is defined by the temperature of the synthesis of the nanocomposite. So while the temperature increases prevailing average particle size of the metal increases and the distribution is blured and shifts toward larger sizes. By a calculation of the total Gibbs energy of possible reduction reactions of nickel chloride and oxide pyrolysis products PAN the possibility of formation of nanocomposites comprising nickel oxide nanoparticles, which are at a higher temperature infrared heating (more than 5000 °C) can be reducted up to zero−valent state at more higher temperature IR heatig.
Ключевые слова Metal carbon nanocomposite, carbon matrix, nickel nanoparticles
Библиографический список

1. Eliseev, A. A. Funktsional'nye nanomaterialy / A. A. Eliseev, A. V. Lukashin / − M. : Fizmatlit, 2010. − 452 s.
2. Alonso, F. A hightly reusable carbon−supported platinum catalyst for the hydrogen−transfer reduction of ketones / F. Alonso, P. Riente, F. Rodriguez−Reinoso, J. Ruiz−Martinez, A. Sepulveda−Escribano, M. Yus // Chem. Cat. Chem. − 2009. − V. 1, N 1. − P. 75—77.
3. Ryashentseva, M. A. Primenenie metallouglerodnykh katalizatorov v protsessakh prevrashcheniya nizshikh alifaticheskikh spirtov / M. A. Ryashentseva, E. V. Egorova, A. I. Trusov, E. R. Nugmanov, S. N. Antonyuk // Uspekhi khimii. − 2006. − T. 75, № 11. − S. 1119—1132.
4. Efimov, M. N. Poluchenie i struktura kataliticheskikh nanokompozitnykh uglerodnykh materialov, soderzhashchikh metally platinovoy gruppy / M. N. Efimov, L. M. Zemtsov, G. P. Karpacheva, M. M. Ermilova, N. V. Orekhova, G. F. Tereshchenko, E. L. Dzidziguri, E. N. Sidorova // Vestn. MITKhT im. M. V. Lomonosova. − 2008. − T. 3, № 1. − S. 66—69.
5. Zemtsov, L. M. Uglerodnye nanostruktury na osnove IK−pirolizovannogo poliakrilonitrila / L. M. Zemtsov, G. P. Karpacheva, M. N. Efimov, D. G. Muratov, K. A. Bagdasarova // Vysokomolek. soed. A. − 2006. − T. 48, № 6. − S. 977—982.
6. Muratov, D. G. Issledovanie elektroprovodnosti i poluprovodnikovykh svoystv novogo uglerodnogo materiala na osnove IK−pirolizovannogo poliakrilonitrila ((S3H3N)n) / D. G. Muratov, V. V. Kozlov, V. V. Krapukhin, L. V. Kozhitov, L. M. Zemtsov, G. P. Karpacheva // Izv. vuzov. Materialy elektron. tekhniki. − 2007. − № 3. − C. 26—30.
7. Umanskiy, Ya. S. Kristallografiya, rentgenografiya, elektronnaya mikroskopiya / Ya. S. Umanskiy, Yu. A. Skakov, A. N. Ivanov, L. N. Rastorguev. − M. : Metallurgiya, 1982. − 632 s.
8. Selivanov, V. N. Ekspressnye metody rentgenovskogo analiza raspredeleniy kristallitov i dislokatsionnoy struktury deformirovannykh polikristallov / V. N. Selivanov, V. F. Smyslov // Materialovedenie. − 1998. − № 4. − S. 2—7.
9. Ryzhonkov, D. I. Nanomaterialy: uchebnoe posobie / D. I. Ryzhonkov, V. V. Levina, E. L. Dzidziguri. − M. : BINOM Laboratoriya znaniy, 2008.
10. Muratov, D. G. Formation of bimetal nanoparticles in the structure of C—Cu—Zn metal−carbon nanocomposite / D. G. Muratov, L. M. Zemtsov, G. P. Karpacheva, E. L. Dzidziguri, E. N. Sidorova // Nanotechnologies in Russia. − 2012. − V. 7, N 1. − P. 62—66.
11. Pat. RF № 2455225. Sposob polucheniya nanokompozita FeNi3/pirolizovannyy poliakrilonitril / L. V. Kozhitov, A. V. Kostikova, V. V. Kozlov. Zaregistrirovano 10.07.2012.
12. Kostikova, A. V. Strukturnye osobennosti nanokompozita FeNi3/C, poluchennogo pri IK−nagreve / A. V. Kostikova, V. V. Kozlov, V. A. Tarala // Izv. vuzov. Materialy elektron. tekhniki. − 2012. − № 2. − S. 61—64
13. Muratov, D. G. Metallouglerodnye nanokompozity na osnove poliakrilonitrila i metallov gruppy zheleza: poluchenie, svoystva, stabil'nost' / D. G. Muratov, L. V. Kozhitov, V. V. Kozlov, A. V. Kostikova, N. A. Valiakhmetova // Tr. VIII Mezhdunar. konf. «Perspektivnye tekhnologii, oborudovanie i analiticheskie sistemy dlya materialovedeniya i nanomaterialov». − Kursk, 2011. − S. 304—318.
14. Zemtsov, L. M. Uglerodnye nanostruktury na osnove IK−pirolizovannogo poliakrilonitrila / L. M. Zemtsov, G. P. Karpacheva, M. N. Efimov, D. G. Muratov, K. A. Bagdasarova // Vysokomolek. soed. A. 2006. − T. 48, № 6. − C. 977—982.
15. Kozlov, V. V. Osobennosti obrazovaniya sistemy polisopryazhennykh svyazey poliakrilonitrila v usloviyakh vakuuma pri termicheskoy obrabotke / V. V. Kozlov, G. P. Karpacheva, V. S. Petrov, E. V. Lazovskaya // Tam zhe. − 2001. T. 43, № 1. − C. 20.
16. Belov, G. V. ASTD — elektronnyy spravochnik po termodinamicheskim, termokhimicheskim i teplofizicheskim svoystvam individual'nykh veshchestv / G. V. Belov, B. G. Trusov. − M. : MGTU im. N. E. Baumana, 1990—1993.
Language of full-text русский
Полный текст статьи Получить
Назад