材料科学
合金
放电等离子烧结
氧化物
制作
冶金
退火(玻璃)
烧结
粉末混合物
纳米颗粒
色散(光学)
降水
粉末冶金
化学工程
纳米技术
替代医学
气象学
病理
工程类
物理
光学
医学
作者
Peng Zhang,Boyang Xu,Jianquan Zhao,Shengming Yin,Youwei Yan,Mi Zhao
标识
DOI:10.1002/srin.202200109
摘要
Mechanical alloying (MA) is widely used to produce oxide‐dispersion‐strengthened (ODS) steels, which are potential candidate structural materials for the next‐generation fusion reactors. Here in this study, two kinds of ODS ferritic alloys, labeled A and B, are prepared through MA, followed by spark plasma sintering (SPS) and annealing. To prepare Alloy A, Fe powder, YH 2 powder, and TiO 2 powder are mixed for MA. To prepare Alloy B, a pre‐alloyed Fe–Cr–W–Y powder is first obtained by gas‐atomization, after which TiO 2 powder is added for MA. Compared with the traditional MA method, where the highly stabilized Y 2 O 3 powder is usually selected, the use of TiO 2 powder successfully reduces the milling time since it should be more easily decomposed and dissolved into the ferrite matrix. Some TiO 2 –Y 2 TiO 5 duplex oxide particles of about 50 nm are found to generate through diffusion‐induced in situ reactions in Alloy A. In Alloy B, in contrast, a high number density of well‐distributed Y 2 O 3 particles of about 20 nm and ultrafine Y 2 Ti 2 O 7 particles within 10 nm are observed. These nanoparticles maintain good coherent interfaces with the matrix, suggesting the precipitation mechanism. Herein, a new route for the efficient fabrication of ODS alloys is provided.
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