Stress corrosion cracking (SCC) has been a serious degradation mechanism of structural materials in light water reactors for decades. Considerable reactor experience has shown that an oxidizing environment, residual stress and susceptible materials combine to produce SCC in structural components of boiling water reactors (BWR). Especially for the cases of SCC in dissimilar metal welds, changes of the residual stress and chemical composition of metal welds in BWR have a huge impact on the corrosion resistance and reliability of structural materials. Through the alteration of water environment and the process of heat treatment for materials, the effect of corrosion mitigation is expected to be achievable. In order to explore the mechanism of SCC in sensitized 316L SS and dissimilar metal welds of 316L SS and Alloy 52, a series of slow strain rate tensile (SSRT) tests in high temperature oxygenated pure water were arranged and conducted in this study. Prior to the SSRT tests, samples were prepared and underwent various pretreatments, including solution annealing and post-weld heat treatment (PWHT). Micro-hardness and residual stresses were profiled adjacent to and in the welded joints of the welded samples. After the SSRT tests, morphologies of the fractured surfaces of the samples were also characterized by using the scanning electron microscope.