Microstructure evolution and mechanical properties of 16Cr-25Ni superaustenitic stainless steel weld metal during 600 °C aging

The effect of high temperature aging on the microstructure evolution and mechanical properties of 16Cr-25Ni superaustenitic stainless steel weld metal was investigated at 600 degrees C for up to 5000 h. Interdendritic micro-size M6C carbide, nano-size M6C and M23C6 carbides were identified in the 200 h aged weld metal, which appeared in clusters and distributed dispersedly. With the aging time increased to 1000 h, the interdendritic region was filled with newly formed precipitates, which were identified as nano-size M12C and M23C6 carbides. Compared with M6C carbide, M12C carbide was preferred to precipitate for lower Gibbs free energy, and the pre-existed M6C carbide had transformed to M12C carbide through the release of C atoms to the matrix. As the aging time further increased to 5000 h, the M12C carbide kept stable with the M23C6 carbide. Due to the precipitation and coarsen of M12C and M23C6 carbides that consumed massive solute atoms from matrix, which weakened the precipitation strengthening effect and suppressed the dynamic strain aging, the tensile properties kept superior stability during aging. The evolution of impact toughness was also closely related to the interdendritic precipitates. As the interdendritic region was occupied by precipitates since the aging time increased from 200 h to 1000 h, the impact toughness rapidly decreased from 76 J to 39 J, and then slightly decreased to 33 J with the aging time increased to 5000 h.(c) 2022 The Author(s). Published by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

Automated summary

The effect of high temperature aging on the microstructure evolution and mechanical properties of 16Cr-25Ni superaustenitic stainless steel weld metal was investigated. The study found that different types of carbides appeared in the aged weld metal, including M6C, M12C, and M23C6 carbides. The precipitation and coarsening of these carbides weakened the precipitation strengthening effect and suppressed the dynamic strain aging, leading to superior stability of the tensile properties during aging. The evolution of impact toughness was also affected by the interdendritic precipitates, with a rapid decrease in toughness as the interdendritic region was occupied by precipitates.