M. Hajjami , A. Oubelkacem , Y. Benhouria , M. Kibbou , I. Essaoudi , A. Ainane
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引用次数: 0
摘要
研究人员利用密度泛函理论(DFT)和蒙特卡罗模拟(MCS)对反包晶Fe3ZnC碳化物的结构、电子和磁属性进行了全面探索。这些反包晶石材料具有独特的结构,其中阳离子和阴离子的位置在包晶石框架内互换。我们的研究包括对 Fe3ZnC 的电子能带结构和状态密度(DOS)进行比较分析,同时考虑到之前的理论和实验研究。了解这些反包晶石材料的能带结构和 DOS 对于它们在磁传感器和磁制冷应用中的有效利用至关重要。我们的研究结果表明,Fe3ZnC 具有铁磁金属特性,尤其是在应用广义梯度近似法(GGA)时。值得注意的是,价带(VB)和导带(CB)之间存在明显的重叠。此外,MCS 预测了反超晶Fe3ZnC 化合物的二阶铁磁到顺磁转变,其特点是居里温度明显较高。这些见解增进了我们对这些材料的了解,为在磁性技术中有效利用它们铺平了道路。
The structural, electronic and magnetic properties of Fe3ZnC anti-perovskite
A comprehensive exploration of the structural, electronic, and magnetic attributes of anti-perovskite Fe3ZnC carbides was carried out using Density Functional Theory (DFT) and Monte Carlo Simulation (MCS). These anti-perovskite materials possess a unique structure where cation and anion positions are interchanged within the perovskite framework. Our study involves a comparative analysis of the electronic band structures and density of states (DOS) for Fe3ZnC, considering prior theoretical and experimental research. Understanding these anti-perovskite materials' band structures and DOS is pivotal for their effective utilization in magnetic sensors and magnetic refrigeration applications. Our results indicate that Fe3ZnC displays ferromagnetic metallic behavior, particularly when applying the Generalized Gradient Approximation (GGA). Notably, there is a significant overlap between the valence (VB) and conduction (CB) bands. Furthermore, MCS predicts a second-order ferromagnetic-to-paramagnetic transition in the anti-perovskite Fe3ZnC compound, characterized by a notably high Curie temperature. These insights advance our understanding of these materials, paving the way for their effective utilization in magnetic technologies.
期刊介绍:
The Chinese Journal of Physics publishes important advances in various branches in physics, including statistical and biophysical physics, condensed matter physics, atomic/molecular physics, optics, particle physics and nuclear physics.
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