Phase Composition and Mechanical Properties Modification in Cr/Ti System by Short-Pulsed High Intensity Ion Beams Treatment

V.I. Shymanski; G.E. Remnev; S.K. Pavlov; V.V. Uglov

doi:10.4028/www.scientific.net/AMM.756.319

Paper Titles

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Mechanical Properties of Spun Castings of Multicomponent Bronze Depending on the Casting Conditions
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Low-Melting Glass-Ceramic Composites with Low Linear Thermal Expansion Coefficient for Radio-Electronics
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Phase Composition and Mechanical Properties Modification in Cr/Ti System by Short-Pulsed High Intensity Ion Beams Treatment
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Investigation of Ultradispersed Powders Fe_xO_y Obtained in the Electric Discharge Plasma
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Experimental Studies of Counter Vortex Flows Modeling
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Gas Injection into Porous Reservoir Partly Saturated by Water
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Experimental Study of Forest Fuel Ignition by the Source of Limited Energy Capacity
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 756Phase Composition and Mechanical Properties...

Phase Composition and Mechanical Properties Modification in Cr/Ti System by Short-Pulsed High Intensity Ion Beams Treatment

Abstract:

In the present the results of research of structure, phase composition and microhardness measurement of the surface layers of the Cr/Ti system treated by short-pulsed high intensity ion beams (HPIB) are presented. It was shown that the HPIB impact on a “coating/substrate” system can serve as an affective way to produce near-surface alloys in the metals. In particular, in the Cr/Ti system the formation of solid solution β-Ti (Cr) as well as titanium carbide TiC_x was revealed. The found changes in structure and phase composition of titanium caused by the HPIB impact allow to increase its microhardness in 2 times.

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Periodical:

Applied Mechanics and Materials (Volume 756)

Pages:

319-324

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.756.319

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Online since:

April 2015

Authors:

V.I. Shymanski*, G.E. Remnev, S.K. Pavlov, V.V. Uglov

Keywords:

Alloying, High Intensity Ion Beams, Mechanical Property, Microhardness, Phase Composition, Structure, Thin Layer, Titanium

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