Publication date: 5 November 2017
Source:Materials & Design, Volume 133
Author(s): J. Lapin, A. Klimová, Z. Gabalcová, T. Pelachová, O. Bajana, M. Štamborská
The in-situ TiAl matrix composites with nominal compositions of Ti-44.5Al-8Nb-0.8Mo-0.1B-xC (at.%), where x is ranging from 1.4 to 4.8at.%, were prepared by casting. The microstructure of the as-cast composites consists of primary (Ti,Nb)2AlC particles distributed in the matrix composed of lamellar γ(TiAl)+α2(Ti3Al) and γ phase regions with a small amount of β/B2 phase. The chemical composition of some coarse carbides is not homogeneous and central regions enriched by C are identified to be (Ti,Nb)C phase. The mean aspect ratio of the primary carbide particles decreases and their volume fraction and shape factor increase with increasing content of C. A linear relationship is identified between the volume fraction of the carbide particles and average content of C in the composites. The heat treatments lead to the formation of fine secondary carbide particles within the matrix. The mean grain size of the as-cast composites increases during the heat treatments. The Vickers hardness, compression yield strength, Charpy impact value and dynamic fracture toughness of the heat-treated composites decrease with the increasing volume fraction of carbide particles. The brittle fracture behaviour of the in-situ composites includes crack deflection, delamination on the matrix-carbide interfaces and pull-out of the carbide particles from the γ matrix.
Graphical abstract
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