Журналы →  Tsvetnye Metally →  2017 →  №11 →  Назад

TO THE 85-th ANNIVERSARY OF ACADEMICAL SCIENCE OF THE URALS
Название Secondary reduction of tantalum in NaCl – KCl and KCl – CaCl2 molten salts
DOI 10.17580/tsm.2017.11.08
Автор Chernyshev A. A., Apisarov A. P., Zaykov Yu. P.
Информация об авторе

Institute of High-Temperature Electrochemistry of the Ural Branch of the Russian Academy of Sciences, Ekaterinburg, Russia:

A. A. Chernyshev, Engineer, e-mail: info@ihte.uran.ru
A. P. Apisarov, Researcher, e-mail: aap@ihte.uran.ru
Yu. P. Zaykov, Research Manager of Instutute

Реферат

We studied the production of Ta powders by the method of secondary reduction in the NaCl – KCl and KCl – CaCl2 melts. The study was carried out without the addition of potential-determining ions in the melt composition in the temperature range of 700–900 oC. The X-ray diffraction analysis and electron microscopy coupled with micro-X-ray analysis showed the formation of tantalum powders with a developed core-shell surface (Ta – TaxOy) during the reduction process. The main stoichiometric oxide phase in the particles shell was Ta2O5. Regularities of the precipitation formation were studied in order to obtain powders of the required size. The use of a calcium chloride containing melt expands the range of the particles up to 1000 μm with a maximum in the region of 20–40 μm. Applying a laser size analysis and BET method, we found that the use of different ratios of the cathode and anode current densities effects the size and specific area of the tantalum powder. The powders with the high specific surface area up to 22.9 m2/g were obtained. The number of the largest particles increases with rising temperature. This is confirmed by the tendency to reduce the specific surface area. It is shown that the dependence of the particle size on the volume fraction of particles depends on the process conditions. For powders obtained in the melts NaCl – KCl and CaCl2 – KCl with the ratio of current densities ic /ia = 1 и ic /ia = 2, the indicative for the particle size distribution was the range of 0.05–10 and 0.5–20 μm, respectively. The increase in the ratio of the current densities to ic /ia = 5 in the melt of CaCl2 – KCl makes it possible to obtain particles with a maximum of 30 μm and a high volume fraction of such particles. We found the optimal electrolysis conditions for obtaining particles suitable for the process of spherization and subsequent use in additive technologies.
This work was carried out with the financial support of the Program of Ural Branch of RAS 2015–2017 “Materials and technologies for nuclear, alternative and renewable power generation” (Project No. 15-20-3-20).

Ключевые слова Tantalum, secondary reduction, electrolysis, sodium, calcium, powder, specific surface, particle size.
Библиографический список

1. Yuan B., Okabe T. H. Production of fine tantalum powder by preform reduction process using Mg–Ag alloy reductant. Journal of Alloys and Compounds. 2007. Vol. 443. pp. 71–80.
2. Lee J. Y., An J., Chua C. K. Fundamentals and applications of 3D printing for novel materials. Applied Materials Today. 2017. Vol. 7. pp. 120–133.
3. Suzuki R. O. Direct reduction processes for titanium oxide in molten salt. JOM. 2007. Vol. 59. pp. 68–71.
4. Baba M., Ono Y., Suzuki R. O. Tantalum and niobium powder preparation from their oxides by calciothermic reduction in the molten CaCl2. Journal of Physics and Chemistry of Solids. 2005. Vol. 66, No. 2–4. pp. 466–470.
5. Baba M., Suzuki R. O. Dielectric properties of tantalum powder with broccolilike morphology. Journal of Alloys and Compounds. 2005. Vol. 392. pp. 225–230.
6. Suzuki R. O., Ishikawa H. Direct Reduction of Vanadium Oxide in Molten CaCl2. Mineral Processing and Extractive Metallurgy. 2008. Vol. 117. pp. 108–112.
7. Barnet R., Kilby K. T., Fray D. J. Reduction of Tantalum Pentoxide Using Graphite and Tin-Oxide-Based Anodes via the FFC-Cambridge Process. Metallurgical and Materials Transactions. 2009. Vol. 40. pp. 150–157.
8. Kikuchi T., Yoshida M., Matsuura S., Natsui S., Tsuji E., Habazaki H., Suzuki R. O. Rapid reduction of titanium dioxide nano-particles by reduction with a calcium reductant. Journal of Physics and Chemistry of Solids. 2014. Vol. 75, No. 9. pp. 1041–1048.
9. Zaykov Yu. P., Isakov A. V., Apisarov A. P., Nikitina A. O. Electrochemical synthesis of iridium powder with high specific surface. Rasplavy. 2016. No. 6. pp. 535–544.
10. Lu C., Fan J., Zhao P., Yuan F. Preparation of hollow silica spheres by DC thermal plasma. Powder Technology. 2014. Vol. 266. pp. 210–217.
11. Powders of non-ferrous metals: reference book. Ed. S. S. Naboychenko. Moscow : Metallurgiya, 1997. 542 p.
12. Kovalevskiy R. A. Electrode processes on indifferent electrode in ionicelectrode liquids on the basis of alkaline and alkali-earth metals liquids in their molten chlorides : Dissertation … of Candidate of Chemical Sciences. Ekaterinburg : IVTE UrO RAN, 1992. 187 p.

Language of full-text русский
Полный текст статьи Получить
Назад