Hydrogen assisted magnesiothermic reduction of TiO2

[Display omitted] •A H2-assisted Mg reduction process to produce Ti metal from TiO2 is described.•Hydrogen destabilizes Ti-O during the reduction and deoxygenation processes.•TiH2 is less prone to oxidation than Ti metal. The development of low cost titanium metal production processes has challenged...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2017-01, Vol.308 (C), p.299-310
Main Authors: Zhang, Ying, Fang, Zhigang Zak, Xia, Yang, Sun, Pei, Van Devener, Brian, Free, Michael, Lefler, Hyrum, Zheng, Shili
Format: Article
Language:English
Subjects:
Deoxygenation
Hydrogen
Magnesium
Reduction
Ti metal powder
TiO2
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Summary:[Display omitted] •A H2-assisted Mg reduction process to produce Ti metal from TiO2 is described.•Hydrogen destabilizes Ti-O during the reduction and deoxygenation processes.•TiH2 is less prone to oxidation than Ti metal. The development of low cost titanium metal production processes has challenged the Ti research and industrial communities around the world for decades. The strong affinity of titanium to oxygen dictates that it is very difficult to produce low-oxygen Ti metal from TiO2 directly. In this paper, a hydrogen assisted magnesiothermic reduction (HAMR) process for producing Ti metal powder from TiO2 powder at relatively low temperatures (⩽750°C) is established. The overall approach is based on the thermodynamic tuning of the relative stability of MgO versus that of Ti-O solid solutions by temporarily alloying the system with hydrogen. It is shown that Ti-H-O solid solutions are less stable than their corresponding Ti-O solid solutions, which changes the reaction of Mg with Ti-O from being thermodynamically unfavorable to being favorable. The key steps for producing pure Ti metal powder from TiO2 involve Mg reduction of TiO2ina hydrogen atmosphere which produces porous TiH2, a heat treatment procedure to consolidate the powder and reduce specific surface area of the powder, and the final step to deoxygenate the powder using Mg in a hydrogen atmosphere to further reduce the oxygen content. This paper systematically examines the changes of oxygen content, phase transformations, and the evolution of the morphology of the particles during the entire process. The results show that this approach has great potential to be a viable method for the production of low-oxygen Ti metal powder from TiO2. In addition, the effect of hydrogen on the oxidation of Ti powder is analyzed using XPS, which reaffirms that titanium hydride is more impervious to surface oxidation than Ti metal, another crucial advantage of using hydrogen atmosphere.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2016.09.066