M. G. Lavrent'ev, V. B. Osvenskii, G. I. Pivovarov, A. I. Sorokin, L. P. Bulat, V. T. Bublik, N. Yu. Tabachkova, “Mechanical properties of (Bi, Sb)$_{2}$Te$_{3}$ solid solutions obtained by directional crystallization and spark plasma sintering”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 2016, Volume 42, Issue 2,Pages 96

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Mechanical properties of (Bi, Sb)$_{2}$Te$_{3}$ solid solutions obtained by directional crystallization and spark plasma sintering

M. G. Lavrent'ev^a, V. B. Osvenskii^a, G. I. Pivovarov^b, A. I. Sorokin^a, L. P. Bulat^c, V. T. Bublik^d, N. Yu. Tabachkova^d

^a GIREDMET Company, State Research and Engineering Center, Moscow, Russia
^b Technological Institute for Superhard and Novel Carbon Materials, Troitsk, Moscow
^c St. Petersburg National Research University of Information Technologies, Mechanics and Optics
^d National University of Science and Technology «MISIS», Moscow

Abstract: We have studied the temperature dependence of the mechanical strength at uniaxial compression for solid solutions based on bismuth and antimony chalcogenides, which were prepared by three methods: (i) vertical zone melting (VZM), (ii) hot extrusion, and (iii) spark plasma sintering (SPS). In the samples of solid solutions obtained by VZM and extrusion, a brittle–ductile transition was observed in a wised temperature interval of 200–350$^\circ$C. In nanostructured SPS samples, transition from brittle to plastic fracture was observed within 170–200$^\circ$C. The room-temperature strength of nanostructured samples was eight to nine times as large as that of VZM samples, and the stress–strain curves of these materials were significantly different. At a temperature of about 300$^\circ$C, the strength of nanostructured solid solutions decreases to nearly zero.

Keywords: Bismuth, Spark Plasma Sinter, Technical Physic Letter, Directional Crystallization, Spark Plasma Sinter Process.

Received: 14.04.2015