Mass transfer behavior of a modified austenitic stainless steel in lithium

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An austenitic stainless steel that was developed to resist neutron damage was exposed to lithium in the high-temperature part of a thermal convection loop for 6700 h. Specimens of this Prime Candidate Alloy (PCA) composed of 65.0 Fe-15.9 Ni-14.0 Cr-1.9 Mo-1.9 Mn-0.4 Si-0.3 Ti-0.05 C (wt %) were exposed at 600 and 570°C in both solution annealed and cold worked forms. The dissolution process was found to be similar to other austenitic alloys in flowing lithium: weight losses of PCA eventually became linearly proportional to exposure time with the specimen surfaces exhibiting porous layers depleted in nickel and chromium. However, the measured weight losses and dissolution rates of these PCA specimens were higher than those of type 316 stainless steel exposed under similar conditions and can be attributed to the higher nickel concentration of the former alloy. The effect of cold work on dissolution rates was less definitive, particularly at 570°C. At longer exposure times, the annealed PCA specimen exposed at 600°C suffered greater dissolution than the cold worked material, while no effect of prior deformation was observed by analysis of the respective surfaces.