M. Oñoro , E. Salas-Colera , S.R. Parnell , V. Martin-Diaconesu , D. Alba Venero , T. Leguey , V. de Castro , M.A. Auger
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引用次数: 0
摘要
在这项工作中,建议添加 Zr 以细化成分为 Fe-14Cr-2W-0.3Zr-0.24Y (wt.%) 的 ODS RAF 钢中的纳米粒子分散。我们使用预合金化雾化粉末(钇直接进入熔体)获得了三批材料,并通过三种不同的加工路线进行生产。第一种工艺基于新开发的 STARS 工艺,旨在避免后续的机械合金化。第二条路线是探索预氧化粉末中机械合金化的影响。第三种方法使用机械合金粉末,而不使用预氧化工艺。ODS 粉末通过热等静压单独固结,然后进行热轧。获得的材料通过小角中子散射(SANS)和 X 射线吸收光谱(XAS)技术进行表征。SANS 和 XAS 分析表明,基于 STAR 路线的材料中不存在氧化物纳米颗粒。SANS 分析证实,机械合金材料中确实存在纳米颗粒。根据 XAS 和 SANS 计算的 A 比率,这些纳米颗粒与 Y2Zr2O7 相联系在一起,被确定为富含 Zr-O 的纳米沉淀物。它们的半径在 3-3.6 纳米之间。XAS 分析结果表明,机械合金化可最大限度地减少预氧化和未预氧化 ODS 粉末之间的初始氧化态差异。
New processing routes for Zr-based ODS ferritic steels
In this work, Zr addition is proposed to refine the nanoparticle dispersion in an ODS RAF steel of composition Fe-14Cr-2W-0.3Zr-0.24Y (wt.%). Three batches of material are obtained using pre-alloyed atomized powder, where yttrium is directly introduced in the melt, and manufactured through three different processing routes. First route is based on the newly developed STARS route that aims to avoid subsequent mechanical alloying. The second route explores the impact of mechanical alloying in pre-oxidized powders. The third route uses mechanically alloyed powders without the pre-oxidation process. The ODS-powders were individually consolidated by hot isostatic pressing and later hot rolled. The obtained materials were characterized by small-angle neutron scattering (SANS) and X-ray absorption spectroscopy (XAS) techniques. SANS and XAS analysis point out the absence of oxide nanoparticles in the material based on the STAR route. SANS analysis confirms that the mechanically alloyed materials do exhibit the presence of nanoparticles. These are identified as Zr-O-rich nanoprecipitates by XAS and the calculated A-ratio by SANS is linked with the phase Y2Zr2O7. Their radii are in the range of 3–3.6 nm. XAS results show that mechanical alloying minimizes the initial differences regarding the oxidation state between the ODS powders with and without pre-oxidation.
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The open-access journal Nuclear Materials and Energy is devoted to the growing field of research for material application in the production of nuclear energy. Nuclear Materials and Energy publishes original research articles of up to 6 pages in length.
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