Magnetic Properties and Microstructure of Sm 5Fe 17-Based Composite Magnets

I. Dirba, H. Sepehri-Amin, K. Skokov, Y. Skourski, K. Hono, O. Gutfleisch
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引用次数: 5

Abstract

We have investigated synthesis, magnetic properties and microstructure of Sm5Fe17-based hard magnetic phase with a Sm20Fe70Ti10 composition. Ultrahigh coercivities, μ0Hc=7.18 T at room temperature and μ0Hc=8.86 T at 10 K, have been achieved. The room-temperature coercivity, determined from high-field pulse measurements, reaches 35% of the anisotropy field μ0Ha=20.7±0.8 T. Further, it is demonstrated that a coercivity of 2.18 T is maintained even at 500 K. The Curie temperature TC of Sm20Fe70Ti10 is 577 K and the calculated exchange stiffness parameter A is 7.72 pJ/m. Detailed transmission electron microscopy investigations show a two-phase microstructure consisting of the Sm5Fe17-based hard magnetic matrix phase with grain size below 200 nm and finer, below 100 nm, Fe2Ti grains. Majority of the Fe2Ti phase is located at the grain boundaries with some finer inclusions found also inside the 5:17 grains. Despite the high fraction of the Fe2Ti grains, nearly single-phase demagnetization loops are observed. In order to enhance Ms, the effect of Ti content on phase constitution, magnetic properties and microstructure was studied in detail. Ms increases and Hc decreases for the Ti-lean compositions.
sm5fe17基复合磁体的磁性能与微观结构
研究了以Sm20Fe70Ti10为基体的sm5fe17硬磁相的合成、磁性能和微观结构。获得了超高矫顽力,室温下μ0Hc=7.18 T, 10k时μ0Hc=8.86 T。高场脉冲测量得到的室温矫顽力达到各向异性场μ0Ha=20.7±0.8 T的35%,在500 K时仍能保持2.18 T的矫顽力。Sm20Fe70Ti10的居里温度TC为577 K,计算得到的交换刚度参数A为7.72 pJ/m。透射电镜观察结果表明,晶粒尺寸小于200 nm的sm5fe17硬磁基相和小于100 nm的Fe2Ti晶粒组成了两相微观结构。大多数Fe2Ti相位于晶界,在5:17晶粒内部也发现了一些较细的夹杂物。尽管Fe2Ti晶粒的比例很高,但仍观察到接近单相的退磁回路。为了提高Ms,详细研究了Ti含量对相组成、磁性能和显微组织的影响。Ti-lean组分的Ms增大,Hc减小。
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