Exploration of homologous substitution element on phase ratio and high temperature properties in high Nb-containing TiAl alloy

To reveal homologous substitution and refined mechanisms, and improve mechanical properties, Ti42Al6Nb 2.5 CxTa alloys were prepared by arc melting. Element distribution, lamellar colony size, length-diameter radio of Ti2AlC phase, tensile properties, and the corresponding influence mechanism were studied. Results show that the relative contents of gamma and Ti2AlC phase increase, the content of alpha 2 phase decreases, when Ta content increases from 0 to 2.0 at%. The relative content of B2 phase increases among the lamellar colonies and the length-diameter ratio of Ti2AlC particle decreases. Lamellar colony size decreases from 24.9 to 10.6 mu m. With the increase of Ta content, the supercooling at the front of the solid-liquid interface increases and the beta phase is refined. The increase of the precipitated phase content leads to the increase of the number of alpha phase heterogeneous nucleation particles, which will refine the lamellar colony. Tensile results show that the strength increases from 238 to 513 MPa and strain increases from 2.7 % to 11.1 % of Ti42Al6Nb 2.5 C1.6Ta alloy when the tested temperature increases from 750 to 950 degrees C. The high temperature tensile properties of the alloy with more Ta content are relatively higher. Ta forms large lattice distortion after solid solution into the matrix due to its large atomic size, and Ta makes more Nb dissolve into the collective to increase the effect of solid solution strengthening. Another reason is the refinement of microstructure. (c) 2022 Elsevier B.V. All rights reserved.

Automated summary

Ti42Al6Nb 2.5CxTa alloys were prepared to investigate the effects of Ta content on the microstructure and mechanical properties. Increasing Ta content led to the increase of gamma and Ti2AlC phases, decrease of alpha 2 phase, and refinement of lamellar colony size. Tensile tests showed an improvement in strength and strain with increasing test temperature, with higher Ta content alloys exhibiting better high temperature properties.