The influence of Ni interlayer thickness on the microstructure, mechanical properties, and corrosion resistance of Zr-4/Nb/Ni/316SS diffusion bonded joints was investigated. The results reveal that the typical interface microstructure of the joints consists of Zr-4/β-(Zr,Nb)/Nb/Ni₃Nb/Ni/316SS. The shear strength of the joints initially increases and subsequently decreases with the increase in Ni interlayer thickness, reaching a peak value of 380 MPa at interlayer thickness of 30 μm. To elucidate the effect of Ni interlayer thickness on the mechanical properties, the microstructural characteristics of the joint interfaces were characterized, and Abaqus simulations were conducted to analyze the residual stress distribution across the interfaces. The comparative analysis of the mechanical properties and fracture behavior, combined with simulation results, indicates that the thicker Ni interlayers are more effective in alleviating residual stress, but excessively thick interlayers lead to a reduction in shear strength due to their enhanced ductility. Additionally, the corrosion resistance of the joints was assessed by full immersion corrosion tests. The results indicate that the corrosion rate decreases with a reduction in Ni interlayer thickness, and the optimum corrosion resistance of joint is achieved at an interlayer thickness of 10 μm. In conclusion, it is recommended that the Ni interlayer thickness needs to be maintained between 10 μm and 30 μm to achieve a balance between mechanical properties and corrosion resistance.