材料科学
位错
极限抗拉强度
产量(工程)
纳米技术
刮擦
延伸率
工作(物理)
结构材料
功能(生物学)
合金
变形(气象学)
纳米尺度
可塑性
机械工程
微观结构
制作
钛合金
纳米光刻
断裂(地质)
计算机科学
纳米-
复合材料
转化式学习
生物相容性材料
材料的强化机理
机械强度
作者
D.D. Zhang,Hengchao Shi,Jinyu Zhang,Jianjun Bian,Yating Ran,Liu Q,Xuanlai Chen,Junhua Luan,Zengbao Jiao,Tao Yang,Jun Sun,Zibin Chen
标识
DOI:10.1038/s41467-026-75563-y
摘要
Cryogenic alloys simultaneously achieving ultrahigh yield strength (YS ≥ 2.0 GPa) alongside substantial uniform elongation (UE) are critically needed, yet fundamentally constrained by the strength-ductility trade-off. Guided by Eshelby’s inclusion theory, we reconcile this challenge by designing a novel hierarchical nano-ordering (HNO) architecture within an ultrafine-grained NiCoCr-based multi-principal element alloy, fabricated via combining additive-manufacturing and tailored post-processing. The HNOs—featuring a controlled size distribution and interfacial properties—comprise dispersed incoherent σ-dispersoids (~70 nm), a high density of bimodal coherent L12 precipitates (~5 and 26 nm) and widespread, highly-distorted local-chemical-orderings (~0.7 nm). This configuration introduces a stepwise increase in elastic strain energy, which in turn triggers the sequential activation of potent dislocation sources. The resulting mobile dislocations engage in extensive and varied interactions with the nano-orderings during deformation, thereby activating cooperative strain-hardening mechanisms. These nano-architectures thus function simultaneously as dislocation generators, strain-hardening enablers, and strengthening agents. Consequently, this HNO-mediated self-hardening and self-ductilizing mechanisms yield an exceptional cryogenic (77 K) property set: YS of ~1.96 GPa, ultimate tensile strength of ~2.35 GPa, and UE of ~22%, surpassing both the cast counterpart and all previously reported advanced alloys. This strategy establishes a transformative paradigm for designing ultrastrong-yet-ductile materials through integrated manufacturing approaches. This work reconciles the challenge of strength-ductility trade-offs in cryogenic alloys by designing a hierarchical nano-ordering architecture within a NiCoCr alloy, achieved via tailored additive-manufacturing and post-processing.
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