磁性合金中的“磁有序强化”现象及其机理探索

项目名称： 磁性合金中的“磁有序强化”现象及其机理探索

项目编号： No.51471048

项目类型： 面上项目

立项/批准年度： 2015

项目学科： 一般工业技术

项目作者： 王建军

作者单位： 东北大学

项目金额： 80万元

中文摘要： 高温金属材料的强化问题一直都是材料研究领域的热点与难点。常规的强化方式（如第二相强化等）在较高温度下因热力学稳定性不足加速材料的失效。本项目根据新发现的高温磁有序强化现象，系统探讨其作为高温结构材料强化方式和提升蠕变性能的可行性。 本申请拟以具有磁有序强化特征的高居里温度Fe基合金为研究对象，通过高温蠕变和高温拉伸试验，研究静态和动态载荷下不同组分铁基合金在高温下的磁有序强化现象。利用DSC、XRD、VSM、MS、SEM、EBSD、HR-TEM、MFM等表征手段，研究不同成分和温度下Fe基合金磁有序相变转变规律，分析Fe基合金中磁有序度和磁畴的变化，揭示塑性变形过程中晶体缺陷与磁畴的交互作用，探讨成分和温度对磁有序强化的影响规律，从微观层面阐明Fe基合金中磁有序强化的机理。本项目的完成可为磁有序强化方式提供一定的理论基础，对于高温金属材料的设计、开发及工程应用具有重要的理论指导。

中文关键词： 铁基合金；磁有序强化；磁畴；塑性变形；晶体缺陷

英文摘要： Strengthening of metallic materials for high temperature is always attractive and a challenge for researchers in material sciences. Those conventional methods to strengthen metallic materials, for example, second phase strengthening, used to deteriorate the materials due to their insufficient thermal stability at elevated temperatures. Therefore, according to the phenomenon of high temperature magnetic ordering strengthening mentioned lately, the feasibility is to be systematically discussed for it to strengthen the high temperature structural materials and improve their creep performances. In the present study, high temperature creep and tensile tests will be conducted to investigate the phenomenon of high temperature magnetic ordering strengthening under the steady state and dynamic loadings for different Fe-based binary alloys with high Curie temperature. By means of differential scanning calorimetry (DSC),X-ray diffraction (XRD), vibrating sample magnetometer(VSM), M?ssbauer spectroscopy(MS), scanning electronic microscopy（SEM）, electron backscattered diffraction（EBSD）, high resolution transmission electron microscopy (HR-TEM) and magnetic force microscopy(MFM), ferromagnetic-paramagnetic phase transition is to be studied for Fe-based alloys with different contents and under different temperatures, and variations of magnetic ordering and magnetic domain in them is to be analyzed. Interactions of crystal defects and magnetic domain during plastic deformation will be determined, and the effects of content and temperature on magnetic ordering strengthening will be discussed. According to experimental results and theoretical analyses, the mechanism of magnetic ordering strengthening for Fe-based alloys is to be clarified on a micro-scale. Concerned with the present study, it is expected to provide some theoretical knowledge based on the magnetic ordering strengthening, and to essentially guide the designing, development and engineering applications for high temperature metallic materials.

英文关键词： Fe-based alloy;magnetic ordering strengthening;magnetic domain;plastic deformation;crystal defect