对偶(语法数字)
比例(比率)
材料科学
纳米技术
物理
量子力学
文学类
艺术
作者
Tiwen Lu,Binhan Sun,Yue Li,Sheng Dai,Ning Yao,Wenbo Li,Xizhen Dong,Xiyu Chen,Jiacheng Niu,Fan Ye,Alisson Kwiatkowski da Silva,Shuya Zhu,Yu Xie,Xiaofeng Yang,Sihao Deng,Jianping Tan,Zhiming Li,Dirk Ponge,Lunhua He,Xian‐Cheng Zhang
出处
期刊:Nature
[Nature Portfolio]
日期:2025-08-27
卷期号:645 (8080): 385-391
被引量:22
标识
DOI:10.1038/s41586-025-09458-1
摘要
The mechanical properties of metallic materials often degrade under harsh cryogenic conditions, posing challenges for low-temperature infrastructures1. Here we introduce a dual-scale atomic-ordering nanostructure, characterized by an exceptionally high number density of co-existing subnanoscale short-range ordering (approximately 2.4 × 1026 m-3) and nanoscale long-range ordering (approximately 4.5 × 1025 m-3) domains, within a metallic solid-solution matrix in a CoNiV-based alloy to improve the synergy of strength and ductility at low temperatures. We observe an ordering-induced increase in dislocation shear stress as well as a more rapid dislocation multiplication owing to the dislocation blocking effect of nanoscale long-range ordering and the associated generation of new dislocations. The latter effect also releases stress concentrations at nanoscale long-range-ordered obstacles that otherwise would promote damage initiation and failure. Consequently, the alloy shows a strength-elongation product of 76 GPa % with a yield strength of approximately 1.2 GPa at 87 K, outperforming materials devoid of such ordering hierarchy, containing only short-range ordered or coherent precipitates of a few tens of nanometres. Our results highlight the impact of dual co-existing chemical ordering on the mechanical properties of complex alloys and offer guidelines to control these ordering states to enhance their mechanical performance for cryogenic applications.
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