Microstructure is an important factor influencing magnetic properties.
微观结构是影响材料磁性能的重要因素。
参考来源 - 纳米永磁材料的微结构与有效各向异性及矫顽力At the same time,the magnetic properties,microstructure and the resulting changes in the corresponding GMI effect are studied.
同时研究了材料微结构、磁学性能以及由此引起的阻抗的变化。
参考来源 - 纳米晶FeCuNbSiB带材磁性及巨磁阻抗效应研究The magnet has the best magnetic properties when the ferrite powder amount reaches to 89wt%.
本实验中磁粉含量为89wt%时,磁体磁性能达到最佳。
参考来源 - 各向异性铁氧体/尼龙注塑母料制备技术的研究Therefore, the study of magnetic properties of magnetic nano-particles is not only for theoretical interests but also valuable for future technological applications.
因此,研究纳米颗粒体系得磁学特性,不仅在理论上有重要的学术价值,为实际应用提供可行的方案,而且是凝聚态物理和纳米磁学的前沿课题。
参考来源 - 纳米颗粒的磁化强度快速翻转特性The phase,morphology and magnetic properties of the production were characterized by X-ray diffraction(XRD),transmission electronic microscopy(TEM) and vibration sample magnetometer(VSM).
分别用X射线衍射(XRD)、透射电子显微镜(TEM)、振动样品磁强计(VSM)对样品的物相、形貌、磁学性能进行了表征。
参考来源 - CuFeThe Electrochemical properties of some compounds were determined,which shows that Metal ions which exit in the compounds are more stable than free ions. The magnetic properties of some compounds were determined,which shows that between M(Ⅱ) ion exhibit antiferromagnetic interreaction.
研究了代表性配合物的电化学性质,说明配合物中的金属离子比自由的金属离子稳定;同时又测定了配合物的变温磁化率,结果表明钴离子之间为反铁磁耦合。
参考来源 - 多官能基羧酸类配合物的合成、结构表征及性质研究·2,447,543篇论文数据,部分数据来源于NoteExpress
应用推荐