Effect of Temperature on the Ti-Fe Alloy Prepared by Molten Salt Electrolysis

Rui Meng Shi; Long Fei Bao; Bo Zhang

doi:10.4028/www.scientific.net/AMR.936.1189

Paper Titles

A Study on Austenite Catalytic Cryogenic Treatment of Cr-W-Mo-V High Alloy Medium-Upper Carbon Steel
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Effect of Forging Process on V-Nb-Ti Microalloyed Non-Quenched and Tempered Steels
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Experimental Study and Calculation of the Precipitation Behavior of Carbides in Fe-5.78Cr-0.35C Alloy during High-Temperature Aging
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Effect of Temperature on the Ti-Fe Alloy Prepared by Molten Salt Electrolysis
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Preparation of Ti-Fe Alloy from Titanium Concentrate by Electro-Deoxidization in CaCl₂
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Study on Atomic Mobility and Molar Volume for FCC Fe-Co Phase
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Molar Volume of Fcc Phase in the Ni-Cr-Mo System
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Effect of Aging Treatment on Phase Transformation of a Pseudoelastic NiTi Alloy
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 936Effect of Temperature on the Ti-Fe Alloy Prepared...

Effect of Temperature on the Ti-Fe Alloy Prepared by Molten Salt Electrolysis

Abstract:

Ti-Fe alloy was prepared by electroanalysis using titanium concentrate as the cathode at 3.1V in CaCl₂ molten salt. The temperature is respectively 850°C and 900°C. The comparison of the results under different temperature shows that the temperature has a significant influence on the diffusion process and the electrolytic products. At 850 °C, the final electrolytic product is the TiFe₂ and Ti discrete ball-type structure with the particle size of 1 μm, while at 900 °C the final product is the TiFe space net structure with the particle size of 3 μm.

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Periodical:

Advanced Materials Research (Volume 936)

Pages:

1189-1194

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.936.1189

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Online since:

June 2014

Authors:

Rui Meng Shi*, Long Fei Bao, Bo Zhang

Keywords:

Diffusion, Molten Salt Electrolysis, Temperature, TiFe, TiFe₂, Titanium Concentrate

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References

[1] A. Kinaei, M. KAydinol. AB Initio Investigation of Feti一Hsystem[J]. International journal of hydro energy, 2007, 32 (13): 2466.

Google Scholar

[2] B. Singh, H. Ryu. Development of New Hydrogen Storage Material Feti(Ni) for Improved Hydrogenation Characteristics [J]. IEEE transactions on electrical and electronic engineering，2006, 24 (l): 1.

DOI: 10.1002/tee.20006

Google Scholar

[3] L., Zhan GM, Pan F. Magnetic Properties and Miro Structure of Fe/Ti Nano2 Seale multilayers [J], 1998, 9 (12): 182.

Google Scholar

[4] X. Yan, X. Chen, A. Grytsiva, et al. Site Preference, Hemodynamic, and Magnetic Properties of the Ternary Laves Phase Ti (Fel一Xalx) (2) with the Crystal Structure of the Mgzn2一TyPe[J]. International journal of materials research, 2006, 97(4): 450.

Google Scholar

[5] J. Koeble, M. Huth. Field Induced Unidirectional Magnetic Anisotropy in Fe2Ti Thin Films [J]. European magnetic materials and applications，2001, 173 (3): 373.

DOI: 10.4028/www.scientific.net/msf.373-376.137

Google Scholar

[6] X. Guo, Z. Guo, Z. Wang. Direct Preparation of Tife Alloy by Electrolytic Reduction from TiO2and Fe2O3[J]. Journal of University of Science and Technology Beijing, 2008, 30(6): 620-624.

Google Scholar

[7] J. Du, Z. Xi, Q. Li, et al. Preparation of TiFe Alloy by Electro-Deoxidization in Molten Salt[J]. Rare Metal Materials and Engineering. 2008, 37(12): 2240~2243.

Google Scholar