The effect of residual stress on the fracture toughness of Ti-6Al-4V produced by laser-based powder bed fusion

Laser powder bed fusion (LPBF) imposes steep thermal gradients, resulting in distortion and the formation of significant residual stresses, which often precipitate in-situ cracking at support interfaces and sharp geometric features. To isolate their influence on structural integrity, we combined fracture mechanics testing with residual stress evaluation on as-built compact tension specimens printed in two orthogonal orientations. The experimentally measured apparent stress-intensity factor was deconvolved into mechanical and residual-stress components, yielding a residual-stress-free fracture toughness (\(\:{K}_{ICeff}\)). Apparent fracture toughness ranged from 25–35 MPa.m ^1/2 , whereas \(\:{K}_{ICeff}\) increased to 45–52 MPa.m ^1/2 . Residual stresses, therefore, depress the material’s residual-stress-free resistance by up to ~ 50% and accentuate orientation-dependent anisotropy. The framework presented offers a route for quantifying process-induced toughness degradation in LPBF alloys.