Email this article Growth of eutectic composites in the InSb–MnSb system
- Authors: Marenkin S.F.1,2, Kochura A.V.3, Fedorchenko I.V.1,2, Izotov A.D.1, Vasil’ev M.G.1, Trukhan V.M.4, Shelkovaya T.V.4, Novodvorsky O.A.5, Zheludkevich A.L.4
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Affiliations:
- Kurnakov Institute of General and Inorganic Chemistry
- Moscow Institute of Steel and Alloys (National University of Science and Technology)
- Southwest State University
- Scientific–Practical Materials Research Centre
- Institute on Laser and Information Technologies
- Issue: Vol 52, No 3 (2016)
- Pages: 268-273
- Section: Article
- URL: https://journals.rcsi.science/0020-1685/article/view/157369
- DOI: https://doi.org/10.1134/S0020168516030110
- ID: 157369
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Abstract
Eutectic composites in the InSb–MnSb system have been grown by the Bridgman method in vertical geometry using a growth charge of eutectic composition. The composites consisted of a [110]-oriented single-crystal InSb matrix and single-crystal MnSb needles aligned in the growth direction. As the solidification rate was raised from 0.5 to 6 mm/h, the length of the needles increased, whereas their diameter dropped from 20 to 4 µm. Further raising the solidification rate led to spontaneous crystallization. Characteristically, the electrical and magnetic properties of the eutectic composites in the InSb–MnSb system were found to exhibit large anisotropy. The low-temperature resistivity of the composites across the needles is four to five times that along the needles. With increasing temperature, the resistivity ratio drops by up to a factor of 2–3. This can be accounted for in terms of a geometric factor. The electrical conductivity of the composites is determined primarily by the MnSb phase, whose volume along the growth direction was considerably larger. According to magnetic measurements, the eutectic composites in the InSb–MnSb system are ferromagnets with a Curie temperature of ≃ 600 K.
About the authors
S. F. Marenkin
Kurnakov Institute of General and Inorganic Chemistry; Moscow Institute of Steel and Alloys (National University of Science and Technology)
Author for correspondence.
Email: marenkin@rambler.ru
Russian Federation, Leninskii pr. 31, Moscow, 119991; Leninskii pr. 4, Moscow, 119049
A. V. Kochura
Southwest State University
Email: marenkin@rambler.ru
Russian Federation, ul. 50 let Oktyabrya 94, Kursk, 305040
I. V. Fedorchenko
Kurnakov Institute of General and Inorganic Chemistry; Moscow Institute of Steel and Alloys (National University of Science and Technology)
Email: marenkin@rambler.ru
Russian Federation, Leninskii pr. 31, Moscow, 119991; Leninskii pr. 4, Moscow, 119049
A. D. Izotov
Kurnakov Institute of General and Inorganic Chemistry
Email: marenkin@rambler.ru
Russian Federation, Leninskii pr. 31, Moscow, 119991
M. G. Vasil’ev
Kurnakov Institute of General and Inorganic Chemistry
Email: marenkin@rambler.ru
Russian Federation, Leninskii pr. 31, Moscow, 119991
V. M. Trukhan
Scientific–Practical Materials Research Centre
Email: marenkin@rambler.ru
Belarus, ul. Brovki 19, Minsk, 220072
T. V. Shelkovaya
Scientific–Practical Materials Research Centre
Email: marenkin@rambler.ru
Belarus, ul. Brovki 19, Minsk, 220072
O. A. Novodvorsky
Institute on Laser and Information Technologies
Email: marenkin@rambler.ru
Russian Federation, Svyatoozerskaya ul. 1, Shatura, Moscow oblast, 140700
A. L. Zheludkevich
Scientific–Practical Materials Research Centre
Email: marenkin@rambler.ru
Belarus, ul. Brovki 19, Minsk, 220072
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