A Computational Understanding of Electronic, Magnetic, Mechanical, Thermoelectric, and Thermodynamic Properties of Rhodium‐Based Full‐Heusler Alloys Rh2MnX (X = Sc, Ti, Zr)

physica status solidi (b) Pub Date : 2023-06-22 DOI:10.1002/pssb.202300168

Joginder Singh, Astha Singh, Nouf H. Alotaibi, Ghazanfar Nazir, C. Lal, S. Dar

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引用次数: 0

Abstract

The present investigation has been carried to know the magnetic talent, mechanical strength, thermoelectric transport properties, and thermal results on Rh2MnX (X = Sc, Ti, Zr) full‐Heusler alloys. The structural investigation presents these alloys to be stable in 225 (Fm‐3m) cubic space group. Electronic results characterize these alloys as metallic in both spin channels. From elastic data results, these compounds are found to be mechanically stable in cubic space group. The mechanical study shows ductile nature for Rh2MnSc while it is brittle for Rh2MnTi and Rh2MnZr. The large value of bulk modulus for these compounds presents their stiffer resistance. The temperature‐dependent thermoelectric transport properties for these materials are calculated. The increasing nature of Ke/τ for all the three compounds presents their conducting nature. Increasing value of power factor with temperature advocates the use of these materials for high‐temperature thermoelectric devices. All the three materials present a large value of total magnetic moment greater than 4 μB and hence can contribute to advanced magnetic materials. The thermodynamic investigation is carried out using Gibbs2 program.

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铑基全Heusler合金Rh2MnX (X = Sc, Ti, Zr)的电子、磁性、机械、热电和热力学性质的计算理解

本文研究了Rh2MnX (X = Sc, Ti, Zr)全Heusler合金的磁性、机械强度、热电输运性质和热结果。组织研究表明，这些合金在225 (Fm‐3m)立方空间群中是稳定的。电子结果表明这些合金在两个自旋通道中都是金属。从弹性数据结果来看，这些化合物在立方空间群中具有机械稳定性。力学研究表明，Rh2MnSc具有延展性，而Rh2MnTi和Rh2MnZr具有脆性。这些化合物的体积模量较大，表现出较强的抗硬性。计算了这些材料随温度变化的热电输运性质。三种化合物的Ke/τ值均呈递增性质，表明它们具有导电性质。随着温度的升高，功率因数的值也在增加，因此这些材料被用于高温热电器件。这三种材料的总磁矩均大于4 μB，可以成为先进的磁性材料。热力学研究采用Gibbs2程序进行。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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physica status solidi (b)

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