Exceptional creep resistance achieved by precipitate and grain boundary strengthening in a modified additively manufactured nickel-based superalloy

蠕动 高温合金 材料科学 冶金 层错能 微观结构 位错 晶界 沉淀硬化 体积分数 降水 材料的强化机理 Laves相 粒度 相(物质) 叠加断层 合金 结构材料 复合材料 氧化物 扩散蠕变 晶界滑移
作者
Rui Li,Zheng Jia,Zhandong Wang,Xiaogang Hu,Shuai Tang,Lijun Song,Guifang Sun
出处
期刊: 卷期号:2 (1): 100178-100178
标识
DOI:10.1016/j.tramat.2026.100178
摘要

In this study, a modified GH4169 superalloy, designated GH4169-CoZr, was designed via computational alloying. Then, specimens of the GH4169 and GH4169-CoZr superalloys were produced via laser directed energy deposition (DED), and their high-temperature creep behavior was comparatively investigated at 595 °C and 825 MPa via creep testing, microstructural characterization, and simulation. Experimental results demonstrated that GH4169-CoZr superalloy has better creep life. The enhanced creep resistance is attributed primarily to a reduction in Laves phase content, combined with grain-boundary strengthening due to Zr segregation. In addition, precipitation strengthening plays a key role, as evidenced by the distinct γ′/γ″ precipitates in GH4169-CoZr, with an average size of approximately 27 nm and a volume fraction of about 31%, which enhances both order strengthening and modulus strengthening. Moreover, the GH4169-CoZr superalloy exhibits a lower stacking fault energy (SFE) compared to GH4169 (151.9 mJ/m 2 vs. 156.8 mJ/m 2 ), which restricts dislocation cross-slip and hinders dislocation climb. Therefore, these synergistic effects of these microstructural characteristics collectively contribute to the superior creep resistance of GH4169-CoZr superalloy. This advancement improves high-temperature creep resistance, broadening composition design and microstructure concepts for future superalloy development.
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