材料科学
钨
退火(玻璃)
维氏硬度试验
软化
压痕硬度
硬化(计算)
冶金
热稳定性
复合材料
热的
微观结构
变形(气象学)
材料的强化机理
纳米压痕
硬度
应变硬化指数
扩散
热机械加工
严重塑性变形
变形机理
作者
Wen Su,Chen Sun,Hao Tain An,Tian Hong Gu
出处
期刊:Key Engineering Materials
日期:2025-11-20
卷期号:1033: 3-9
摘要
As aerospace, nuclear engineering, and other high-technology industries continue to advance, the demands for material properties have grown more stringent. Strengthened via the intrinsic thermally stable element tungsten (W) with the ductile γ phase, tungsten heavy alloys (WHAs) have emerged as critical materials for extreme service conditions in multiple fields due to their high density, outstanding strength, radiation resistance, and excellent high-temperature performance. However, their application is limited by certain drawbacks such as high temperature/irradiation conditions, interfacial weakening and room-temperature brittleness. This study investigates the effect of annealing on the microstructural evolution and hardness behaviour of W-Ni-Fe and W-Ni-Cu alloys through the Vickers hardness tests, crystal structure, morphology and elemental distribution analysis. The W-Ni-Fe and W-Ni-Cu alloys exhibit remarkable hardness stability during annealing, with less affected by temperature, confirming the excellent thermal stability. W-Ni-Fe alloys exhibit softening phenomena during high-temperature annealing, while the W-Ni-Cu alloys demonstrate enhanced hardness through annealing. This discrepancy is originally caused by the differences in the diffusion behaviour of the two binder phases (NiFe/NiCu) at elevated temperatures and their distinct interfacial interaction mechanisms with the W matrix.
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