Clarifying the effect of irradiation and thermal treatment on the austenitic microstructure and austenitic hardening in austenitic stainless steel weld metal

Xiaodong Gao, Xiaodong Lin, Lining Xu, Yaolei Han, Qunjia Peng, Lijie Qiao
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Abstract

The weld cladding on the inner surface of nuclear pressure vessels due to irradiation damage and thermal effect presents to a safety issue. Unfortunately, the effect of irradiation and long-term thermal treatment on the austenitic microstructure and austenitic hardening in austenitic stainless steel weld metals (ASSWMs) remains poorly understood. In this study, the effects of irradiation and thermal treatment on the austenitic microstructures and austenitic hardening of 308L ASSWMs were investigated using nanoindentation, atom probe tomography and transmission electron microscopy. The results suggested that irradiation resulted in the formation of Ni/Si-rich clusters, voids, and Frank loops in austenite, thereby inducing austenitic hardening. Subsequently, thermal treatment decreased the size and the number of Frank loops in irradiated austenite, which had a minor effect on austenitic hardening. However, thermal treatment promoted the growth of Ni/Si-rich clusters and void formation, which have a primary effect on austenitic hardening, thereby enhancing the hardening of irradiated austenite. Furthermore, thermal treatment has little effect on the microstructure and hardening of austenite. Then, irradiation promoted the formation of Ni/Si-rich clusters, voids, and Frank loops in thermally treated austenite, resulting in austenitic hardening. The interaction of irradiation and thermal treatment can promote the formation of voids. The austenitic hardening was mainly due to the contribution of Frank loops, voids, and Ni/Si-rich clusters, which acted as short-range barriers by pin-moving dislocations.
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阐明辐照和热处理对奥氏体不锈钢焊接金属中奥氏体显微组织和奥氏体硬化的影响
由于辐照损伤和热效应,核压力容器内表面的焊缝熔覆是一个安全问题。遗憾的是,辐照和长期热处理对奥氏体不锈钢焊缝金属(ASSWMs)的奥氏体显微组织和奥氏体硬化的影响仍然知之甚少。本研究采用纳米压痕法、原子探针断层扫描和透射电子显微镜研究了辐照和热处理对 308L ASSWM 的奥氏体微观结构和奥氏体硬化的影响。结果表明,辐照导致奥氏体中形成富含 Ni/Si- 的团簇、空隙和弗兰克环,从而诱导奥氏体硬化。随后,热处理降低了辐照奥氏体中弗兰克环的尺寸和数量,对奥氏体硬化的影响较小。然而,热处理促进了富含 Ni/Si 的簇的生长和空隙的形成(这对奥氏体硬化有主要影响),从而增强了辐照奥氏体的硬化。此外,热处理对奥氏体的微观结构和硬化影响很小。然后,辐照促进了热处理奥氏体中富镍/硅簇、空隙和弗兰克环的形成,从而导致奥氏体硬化。辐照和热处理的相互作用可促进空隙的形成。奥氏体硬化主要是由于弗兰克环、空隙和富含镍/硅的簇的作用,它们通过针状位错移动起到了短程屏障的作用。
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