Influence of Mechanical Activation on Synthesis of Compounds in the B/C - Mg/Al/Ca System

Authors

  • Farit Kh. Urakaev Institute of Mineralogy and Petrography, Siberian Division, Russian Academy of Sciences, prospekt akademika Koptyuga, 3, Novosibirsk, 630090, Russia
  • Vyacheslav S. Shevchenko Institute of Mineralogy and Petrography, Siberian Division, Russian Academy of Sciences, prospekt akademika Koptyuga, 3, Novosibirsk, 630090, Russia
  • Vladimir V. Boldyrev Novosibirsk State University, Pirogova street, 2, Novosibirsk, 630090, Russia

DOI:

https://doi.org/10.18321/ectj589

Abstract

The possibility of mechanochemical synthesis and influence of mechanical activation on thermal synthesis
of borides and boron carbides of mass-low metals is investigated. The opportunity of mechanochemical
synthesis in the mill AGO-2 of such compounds as AlB2 and CaC2B2 is established. Influence of mechanical activation in the mill SPEX 8000 on synthesis of such compound as Mg0.5Al0.5B2 is shown. Mechanical activation also influences on the process of thermal synthesis: compound Mg0.5Al0.5B2 is obtained in the conditions inaccessible to traditional thermal synthesis; formation of compound Mg1-xAlxB2 in literature up to x = 0.4 was established on shifts of reflexes (002) and (110) pure MgB2 aside the large corners; in our case x = 0.5 and as it was necessary to expect shifts of these reflexes exceeds shifts measured in literature only for x ≤ 0.4. Features of synthesis in systems containing metal magnesium are considered. The opportunity of application of crystalline boron for mechanochemical synthesis of borides and boron carbides of mass-low metals is established, that it was not represented probable to make in its ceramic synthesis. We revealed also that thermal analysis in conditions of helium results in crystallization almost all activated samples, and the analysis of received X-ray reflexes unambiguously allows to assert that mechanical activation accelerates synthesis of reaction products in the investigated systems in comparison with the traditional methods of its synthesis.

References

(1). O. Knoteck, A. Schrey, Hard and Protective Materials, in D. Glocker, S.I. Shah (eds.), Handbook of Thin Film Process Technology, Institute of Physics Publishing, Philadelphia, PA, 1995, p. Z1.0:12.

(2). Merzhanov, A.G. Combustion processes and the synthesis of materials, ISMAN, Chernogolovka, 1998.

(3). http://www.peakpeak.com/~jdavis/boron/boron.html.

(4). Nagamatsu, J., Nakagawa, N., Muranaka, T., and Akimitsu, J., Superconductivity at 39K in magnesium
diboride, Nature. 2001(1 MARCH). V. 410. pp. 63-64.

(5). Akimitsu, J., Takenawa, K., Suzuki, K., Harima, H., Kuramoto, Y., High-temperature ferromagnetism
in CaB2C2, Science. 2001(10 August). V. 293. pp. 1125-1127.

(6). Slusky, J.S., Rogato, N., Regan, K.A., Hayward, M.A., Khalifan, P., He, T., Inumaru, K., Loureiro, S.M., Haas, M.K., Zandbergen, H.W., and Cava, R.J., Loss of superconductivity with the addition of Al to MgB2 and a structural transition in Mg1-xAlxB2, Nature. 2001(15 MARCH). V. 410. pp. 343-345.

(7). Ivanovskii, A.L., Medvedeva, N.I., Zubkov, V.G., and Bamburov, V.G., Synthesis, Physicochemical Properties, and Materials Science Aspects of Superconducting MgB2 and Related Phases, Russian Journal of Inorganic Chem. 2002. V. 47. No. 4. P. 584-597.

(8). Medvedeva, N.I., Medvedeva, Yu. E., and Ivanovskii, A. L., Electronic Structure of Ternary Boron-Containing Phases YCrB4, Y2ReB6, and MgC2B2, Doklady Physical Chemistry. 2002. V. 383. Nos. 1–3. pp. 75-80.

(9). Zaluska, A., Zaluski, L., and Strцm-Olsen, J.O., Lithium-beryllium hydrides: the lightest reversible metal hydrides, Journal of Alloys and Compounds. 2000. V. 307. No. 1-2. P. 157-166.

(10). Noskova, N.I., and Volkova, E.G., In situ Investigations of Deformation in Nanocrystalline Fe73.5Cu1Nb3Si13.5B9 Alloy, The Physics of Metals and Metallography. 2001. V. 92. No. 4. pp. 421-425.

(11). Urakaev, F.Kh., Shevchenko, V.S., Chupakhin, A.P., Yusupov, T.S., and Boldyrev, V.V., Application of Mechanically Induced Combustive Reactions for Processing of Geologic Materials, Journal of Mining Science. 2002. V. 37. No. 6. pp. 626-636.

(12). Kubaschewski, O., Alcock, C.B., and Spencer, P.J., Materials Thermochemistry, Sixth Edition. Pergamon Press – Oxford, New York-Seoul-Tokyo, 1993.

(13). Konstanchuk, I.G., Ivanov, E.Yu., Bokhonov, B.B., and Boldyrev, V.V., Hydriding properties of mechanically alloyed icosahedral phase Ti45Zr38Ni17, J. Alloys Compounds. 2001. V. 319. pp. 290-295.

(14). Urakaev, F.Kh., and Boldyrev, V.V., Inorganic Materials. 1999. V. 35. Nos. 2, 3, 4: pp. 180, 302, 405.

(15). Urakaev, F.Kh., and Boldyrev, V.V., Mechanism and Kinetics of Mechanochemical Processes in Comminuting Devices. 1. Theory, Powder Technology. 2000. V. 107. Issue 1-2. pp. 93-107.

(16). Idem, 2. Applications of the Theory. Experiment, Ibid. Issue 3. pp. 197-206.

(17). Urakaev, F.Kh., Shevchenko, V.S., and Boldyrev, V.V., Role of the Heat of Reaction in Modeling
Mechanochemical Processes. Dokl. Phys. Chem. 2001. V. 377. No. 1-3. pp. 59-61.

(18). Urakaev, F.Kh., Takacs, L., Soika, V., Shevchenko, V.S., Chupakhin, A.P., and Boldyrev, V.V., The mechanisms of formation of “hot spots” in mechanochemical reactions between metals and sulfur, Russian Journal of Physical Chemistry. 2001. V. 75. No. 12. pp. 1997-2001.

(19). Urakaev, F.Kh., Takacs, L., Soika, V., Shevchenko, V.S., Chupakhin, A.P., and Boldyrev, V.V., Phenomenological description of combustive reactions of thermite compositions in mechanochemical
reactors for the synthesis of metal sulphides as an example. Chemistry for Sustainable Development. 2002. V. 10. No. 1-2, pp. 197-202: - http://www.sbras.ru/PSB/list.phtml?eng+9+2002+1-2.

(20). Urakaev, F.Kh., Takacs, L., Shevchenko, V.S., Chupakhin, A.P., and Boldyrev, V.V., Simulation of the Combustion of Thermite Compositions in Mechanochemical Reactors for the Example of the Zn–Sn–S System, Russian Journal of Physical Chemistry. 2002. V. 76. No. 6. pp. 939-945.

(21). Urakaev, F.Kh., Shevchenko, V.S., Nartikoev, V.D., Ripinen, O.I., Tolstykh, O.N., Chupakhin, A.P., Yusupov, T.S., and Boldyrev, V.V., Mechano-thermite opening of mineral raw materials, Chemistry for Sustainable Development. 2002. V. 10. No. 3. pp. 355-362: -http://www.sbras.ru/PSB/list.phtml?eng+9+2002+3.

(22). Oliveira, M.N., Conde, O., Synthesis and properties of BxCyNz coatings, Journal of Materials Research. 2001. V. 16. No. 3. pp. 734-743.

(23). Labruquere, S., Pailler, R., Guette, A., Naslain, R., Internal protection of C/C composites by boron-based compounds, Journal of the European Ceramic Soc. 2002. V. 22. No. 7. pp. 987-999.

(24). Levashov, E.A., Larikhin, D.V., Shtanskii, D.V., Rogachev, A.S., Grigiryan, A.E., and Mur, J.J., Influence of technological parameters in SVS compacting on composition, structure and properties functional gradient targets on basis B-CN-Ti system, Tsvetnye metally (Nonferrous metals). 2002. No. 5. pp. 49-55 (in Russian).

Downloads

Published

2003-01-15

How to Cite

Urakaev, F. K., Shevchenko, V. S., & Boldyrev, V. V. (2003). Influence of Mechanical Activation on Synthesis of Compounds in the B/C - Mg/Al/Ca System. Eurasian Chemico-Technological Journal, 5(1), 49–54. https://doi.org/10.18321/ectj589

Issue

Section

Articles