材料科学
金属
冶金
纳米技术
微观结构
铜
光电子学
镍
结晶学
碳纤维
作者
Shasha Huang,Zhengxiong Su,Shihua Ma,Baichuan Xu,Haijun Fu,Xuepeng Xiang,Wenyu Lu,Ailin Yang,Zhongtao Li,Sergei L. Dudarev,Chenyang Lu,Zhenggang Wu,Shijun Zhao
标识
DOI:10.1038/s41467-026-73093-1
摘要
Materials capable of withstanding extreme conditions are essential for advanced fission and fusion technologies. The development of irradiation-tolerant structural materials hinges on the suppression of defect evolution that could lead to mechanical degradation. In this study, we present a novel strategy to effectively immobilize irradiation-induced defects through tuning the degree of local lattice distortion, an intrinsic characteristic of concentrated solid solution alloys. Our results show that increasing the degree of local lattice distortion significantly suppresses irradiation-induced microstructural changes. Notably, the single-phase binary Ni80Mo20 alloy, which exhibits the highest recorded degree of local lattice distortion (4.82% atomic size mismatch), demonstrates markedly frozen defect motion, resulting in negligible irradiation-induced effects. Our findings suggest that irradiation-resistant materials can be developed by engineering local lattice distortion, offering an easy-to-manipulate pathway to designing irradiation-tolerant metallic alloys. This study examines severe lattice distortions in concentrated solid solutions, enabling an energy landscape that immobilizes vacancies and interstitials which curbs their harmful evolution under irradiation conditions.
科研通智能强力驱动
Strongly Powered by AbleSci AI