Crystallographic Features of Nanosized Titanium Carbide Produced from Titanium and Carbon in a Planetary-Ball Mill

Structural changes that occur in titanium during grinding of a powder mixture of titanium and carbon in an AIR-015M planetary-ball mill are studied. Grinding of the powder mixture results in the formation of titanium carbide single crystals with particles 7–50 nm in size over the entire reaction zon...

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Bibliographic Details
Published in:Powder metallurgy and metal ceramics 2016-09, Vol.55 (5-6), p.251-258
Main Authors: Saviak, M. P., Mel’nik, O. B., Uvarova, I. V., Kotko, A. V., Udovik, O. O.
Format: Article
Language:English
Subjects:
Carbides
Carbon
Ceramics
Characterization and Evaluation of Materials
Chemistry and Materials Science
Composites
Formations
Glass
Grinding
Lattices
Manufacturing Technology
Materials Science
Metallic Materials
Mills
Natural Materials
Nuclei
Powders
Properties of Powders and Fibers
Theory
Titanium
Titanium carbide
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Summary:Structural changes that occur in titanium during grinding of a powder mixture of titanium and carbon in an AIR-015M planetary-ball mill are studied. Grinding of the powder mixture results in the formation of titanium carbide single crystals with particles 7–50 nm in size over the entire reaction zone. At the initial stage of grinding, texturing of titanium occurs and the titanium lattice cell increases in volume, thus inducing internal stresses. Based on these data, it is suggested that the introduction of carbon into the strained titanium particles leads to stacking faults in the titanium hcp lattice, acting as nuclei of fcc titanium carbide in the titanium sites fragmented. Single-crystal TiC 10–20 nm nanoparticles are formed in these sites. The length of titanium–carbon contacts naturally increases with grinding time, giving rise to more nuclei of the new fcc phase. This promotes a mechanically induced self-propagating reaction. The heat generated in the reaction contributes to the sintering of titanium carbide nanoparticles. This results in the formation of particle aggregates 0.1–0.5 μm in size.
ISSN:1068-1302
1573-9066
DOI:10.1007/s11106-016-9800-5