Mechanical properties of aluminum matrix composite reinforced with titanium carbide

An original method for the production of metal matrix nanocomposites has been proposed, which consists of depositing carbide structures 4–12 nm thick onto the surface of particles of aluminum powder by molecular layering, mixing the resulting dispersed particles with particles of pure metal in the r...

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Bibliographic Details
Published in:Journal of physics. Conference series 2024-08, Vol.2817 (1), p.12014
Main Authors: Zemtsova, E G, Morozov, N F, Semenov, B N, Smirnov, V M, Venatovskaya, L A
Format: Article
Language:English
Subjects:
Aluminum
Aluminum base alloys
Aluminum matrix composites
Dispersion hardening
Mechanical properties
Metal matrix composites
Nanocomposites
Particulate composites
Plastic deformation
Sintering (powder metallurgy)
Stress-strain curves
Titanium carbide
Workpieces
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Summary:An original method for the production of metal matrix nanocomposites has been proposed, which consists of depositing carbide structures 4–12 nm thick onto the surface of particles of aluminum powder by molecular layering, mixing the resulting dispersed particles with particles of pure metal in the required concentration, then pressing and sintering the resulting mixture. The resulting workpieces are subjected to intense plastic deformation by high-pressure torsion, which not only significantly reduces porosity, ensures a uniform distribution of reinforcing particles throughout the volume, and destroys carbide shells on the surface of dispersed particles, but also grinds aluminum particles. Experimental stress-strain curves of the synthesized composites were constructed and the contribution of various hardening mechanisms to the final hardening of the metal matrix composite was assessed. In metal matrix composites synthesized by this method, with small fractions of the volume content of reinforcing titanium carbide particles (less than 0.1%), almost twofold hardening and a threefold increase in the yield strength are observed with a slight reduction in plastic deformation before failure.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/2817/1/012014