Surface residual stress and phase stability in unstable -type Ti-15Mo-5Zr-3Al alloy manufactured by laser and electron beam powder bed fusion technologies

The differences between the physicochemical properties of the laser and electron beam powder bed fusion (Land EB-PBF) methods are yet to be explored further. In particular, the differences in the residual stress and phase stability of alloys with unstable phases remain unexplored. The present work is the first to systematically investigate how the heat source type and process parameters affect the surface residual stress and phase stability of an unstable 13-type titanium alloy, Ti-15Mo-5Zr-3Al. The surface residual stress and 13-phase behavior were studied using high-precision X-ray diffraction (HP-XRD). Significant differences were observed between the two methods. The L-PBF-made specimens exhibited tensile residual stresses of up to 400 MPa in the surface area. HPXRD analysis revealed a stress-induced lattice distortion, interpreted as a transitional state between the 13-phase and alpha"-phase. In contrast, the EB-PBF-made specimens showed no significant residual stress and had an undistorted 13-phase coexisting with the hexagonal alpha-phase caused by elemental partitioning. This study provides new insights into the previously neglected effects of L-PBF and EB-PBF in unstable 13-type titanium alloys.