Adjusting the γ/α2 and Ti2AlC phase on microstructure evolution and improving mechanical properties at room and elevated temperatures with the addition of Ta

Alloys of Ti-46Al-6Nb-2.5C-xTa (at. %) were prepared to adjust gamma/alpha(2) phase, refine microstructures, and improve mechanical properties at room and elevated temperatures simultaneously. Phase contents, lamellar colony size, Ti2AlC morphology, compressive and tensile properties, and related mechanisms were discussed. The results show that the relative content of the gamma phase increases and the relative content of the alpha(2) phase decreases when Ta content increases from 0 to 2.0 at. %. The solid solution effect of Ta in reinforcing phases contributes to the absence of brittle B2 phase. The content of small length-diameter ratios of Ti2AlC particles increases. The lamellar colony size decreases from 29.9 to 21.6 mu m. The constitutional undercooling and heterogeneous nucleation are increased by Ta during the solidification process. Compressive strength increases from 1974 to 2330 MPa when Ta content increases to 0.8 at. %, and the strain increases from 19.8 to 28.2% when Ta content increases to 1.2 at. %. The tensile strength of the Ti-46Al-6Nb-2.5C-2.0Ta alloy increases from 460 to 503 MPa and its strain increases from 4.1 to 8.3%, when temperature increases from 750 to 950 degrees C. The refinement of lamellar colonies and Ti2AlC, solid solution of Ta, and the ratio of gamma/alpha(2) are the main reasons for improving mechanical properties of Ti-46Al-6Nb-2.5C-2.0Ta alloy.

Automated summary

By adjusting the content of alloying elements, the microstructure and mechanical properties of Ti-46Al-6Nb-2.5C-xTa alloys can be improved simultaneously at room and elevated temperatures.