Authors | D.G. Muratov1,2 , L.V. Kozhitov1 , S.G. Emelyanov3 , A.V. Vasilyev1,2, A.V. Popkova4, A.A. Pavlova5 |
Affiliations | 1 National University of Science and Technology MISiS, 4, Leninskiy prosp., 119049 Moscow, Russia 2 A.V.Topchiev Institute of Petrochemical Synthesis, RAS, 29, Leninskiy prosp., 119991 Moscow, Russia 3 Southwest State University, 94, 50 let Oktyabrya st., 305040 Kursk, Russia 4 Tver State University, 33, Zhelyabova st., 170100 Tver, Russia 5 National research Tomsk State University, 36, Lenin ave., 634050 Tomsk, Russia |
Е-mail | muratov@ips.ac.ru |
Issue | Volume 8, Year 2016, Number 3 |
Dates | Received 11 May 2016; published online 03 October 2016 |
Citation | D.G. Muratov, L.V. Kozhitov, S.G. Emelyanov, et al., J. Nano- Electron. Phys. 8 No 3, 03037 (2016) |
DOI | 10.21272/jnep.8(3).03037 |
PACS Number(s) | 82.50.Bc |
Keywords | Synthesis (27) , Metal-carbon composites, Nanoparticles of Fe-Co-Ni, Saturation magnetization (5) , Coercive force (2) , Squareness ratio. |
Annotation | Nanoparticles of Fe-Co-Ni three-component alloy capsulated into carbon matrix were synthesized. Structure, phase composition and magnetic properties of obtained materials were defined by diffractometry and magnetometry. It was established that composition of nanoparticles is determine by synthesis temperature, because nanoparticles of three-component alloy are forms by dissolution of cobalt in Fe-Ni alloy. Magnetization of Fe-Co-Ni/C nanocomposites and coercive force increases from 26 up to 58 A·m2/kg during temperature increase that relates with growth of particles size and increase of cobalt content in the alloy. |
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