Structure and Properties of Surface Alloys in Ti-Y System

Yurii F. Ivanov; Anton D. Teresov; Olga Ivanova; Victor Gromov; Sergei Raikov; Kirill V. Sosnin; Olga Semina; Kseniya Alsaraeva

doi:10.4028/www.scientific.net/AMR.1013.229

Paper Titles

Structural Phase Transformations and Morphological Changes of Icosahedral Small Copper Particles in Temperature Fields and Reactive Media
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Cu-Ag Solid Solutions Formation and Properties upon Severe Plastic Deformation
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Temperature Effect on Solid Solution Formation Mechanism and Kinetics of Cu-Zn System under High Pressure Torsion
p.218

Formation of Surface Layers in Cu-C System
p.224

Structure and Properties of Surface Alloys in Ti-Y System
p.229

Models of Dislocation Formation and Mechanical Twinning by Local Reversible Martensitic Transformations in FCC Nanocrystals
p.234

Effect of Length and Cross-Sectional Area on Ni₃Fe Alloy Plasticity
p.242

Two-Level Model of Inelastic Deformation of FCC Polycrystals and Structure Evolution Description
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Mathematical Modelling of the Flow Structure and Heat Transfer in a Channel with a Porous Insert
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1013Structure and Properties of Surface Alloys in Ti-Y...

Structure and Properties of Surface Alloys in Ti-Y System

Abstract:

The doping of the surface layer of titanium by the yttrium, oxygen and carbon was implemented. Irradiation of the doped layer by intense electron beam leads to the formation of the multiphase structure and the nanosubmicron range having a high microhardness (at 3-fold higher than the hardness of the original structure) and a low coefficient of friction (6 times lower than the friction coefficient of the starting material).

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Periodical:

Advanced Materials Research (Volume 1013)

Pages:

229-233

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1013.229

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Online since:

October 2014

Authors:

Yurii F. Ivanov*, Anton D. Teresov, Olga Ivanova, Victor Gromov, Sergei Raikov, Kirill V. Sosnin, Olga Semina, Kseniya Alsaraeva

Keywords:

Electric Explosion, Electron Beam Treatment, Phase Composition, Structure, Surface

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