Valence electron structures dependences of structural stability and properties of REX3(RE=rare earth; X=In, Tl) and RE(In, Co)3 alloys

doi:10.1088/1674-1056/ad7575

中国物理B ›› 2024, Vol. 33 ›› Issue (11): 116102-116102.doi: 10.1088/1674-1056/ad7575

Valence electron structures dependences of structural stability and properties of REX₃(RE=rare earth; X=In, Tl) and RE(In, Co)₃ alloys

Boyang Li(李博洋), Yongquan Guo(郭永权)†, Yi-Chen Feng(冯奕晨), Xinze Wang(王鑫泽), and Wei Liu(刘葳)

School of Energy Power and Mechanical Engineering, North China Electric Power University, Beijing 102206, China

收稿日期:2024-05-15 修回日期:2024-08-20 接受日期:2024-08-30 出版日期:2024-11-15 发布日期:2024-11-15

Valence electron structures dependences of structural stability and properties of REX₃(RE=rare earth; X=In, Tl) and RE(In, Co)₃ alloys

Boyang Li(李博洋), Yongquan Guo(郭永权)†, Yi-Chen Feng(冯奕晨), Xinze Wang(王鑫泽), and Wei Liu(刘葳)

School of Energy Power and Mechanical Engineering, North China Electric Power University, Beijing 102206, China

Received:2024-05-15 Revised:2024-08-20 Accepted:2024-08-30 Online:2024-11-15 Published:2024-11-15
Contact: Yongquan Guo E-mail:yqguo@ncepu.edu.cn

1. 2024-116102-SI.pdf(255KB)

摘要/Abstract

摘要： Intermetallic compounds $RE$In$_{3}$ ($RE={\rm rare}$ earth) have attracted much attention due to their unique characteristics: crystal field effect, Kondo effect, superconductivity, heavy fermion, and antiferromagnetism, and their cobalt diluted alloys exhibit the ferromagnetic half-metallic characteristics at room temperature. In this study, an empirical electron theory (EET) is employed to investigate systemically the valence electronic structure, the thermal and magnetic properties of $REX_{3}$ and their cobalt diluted alloys for revealing the mechanism of physical properties. The calculated bond length, melting point, and magnetic moment match the experimental ones very well. The study reveals that structural stability and physical properties of $REX_{3}$ and their cobalt dilute alloys are strongly related to their valence electron structures. It is suggested that the structural stability and cohesive energy depend upon the covalent electron, the melting point is modulated by covalent electron pair, and the magnetic moment is originated from 3d magnetic electron. The ferromagnetic characteristics of Co-diluted $RE$In$_{3}$ alloys is originated from the introduction of strong ferromagnetic Co atom, but, a competition is caused between the electron transition from valence electron to magnetic electron on d orbit and its reversal electron transformation with increasing the content of cobalt, which results in the formations of diluted magnetic Gd(In,Co)$_{3}$ alloy with minor amount of cobalt and strong magnetic Nd(In,Co)$_{3}$ alloy with doping more Co atoms.

关键词: $REX_{3}$, cobalt dilute alloy, valence electron structures, empirical electron theory, moment

Abstract: Intermetallic compounds $RE$In$_{3}$ ($RE={\rm rare}$ earth) have attracted much attention due to their unique characteristics: crystal field effect, Kondo effect, superconductivity, heavy fermion, and antiferromagnetism, and their cobalt diluted alloys exhibit the ferromagnetic half-metallic characteristics at room temperature. In this study, an empirical electron theory (EET) is employed to investigate systemically the valence electronic structure, the thermal and magnetic properties of $REX_{3}$ and their cobalt diluted alloys for revealing the mechanism of physical properties. The calculated bond length, melting point, and magnetic moment match the experimental ones very well. The study reveals that structural stability and physical properties of $REX_{3}$ and their cobalt dilute alloys are strongly related to their valence electron structures. It is suggested that the structural stability and cohesive energy depend upon the covalent electron, the melting point is modulated by covalent electron pair, and the magnetic moment is originated from 3d magnetic electron. The ferromagnetic characteristics of Co-diluted $RE$In$_{3}$ alloys is originated from the introduction of strong ferromagnetic Co atom, but, a competition is caused between the electron transition from valence electron to magnetic electron on d orbit and its reversal electron transformation with increasing the content of cobalt, which results in the formations of diluted magnetic Gd(In,Co)$_{3}$ alloy with minor amount of cobalt and strong magnetic Nd(In,Co)$_{3}$ alloy with doping more Co atoms.

Key words: $REX_{3}$, cobalt dilute alloy, valence electron structures, empirical electron theory, moment

中图分类号: (Crystal binding; cohesive energy)

61.50.Lt

75.50.-y (Studies of specific magnetic materials) 78.40.Kc (Metals, semimetals, and alloys) 31.10.+z (Theory of electronic structure, electronic transitions, and chemical binding)

Boyang Li(李博洋), Yongquan Guo(郭永权), Yi-Chen Feng(冯奕晨), Xinze Wang(王鑫泽), and Wei Liu(刘葳). Valence electron structures dependences of structural stability and properties of REX₃(RE=rare earth; X=In, Tl) and RE(In, Co)₃ alloys[J]. 中国物理B, 2024, 33(11): 116102-116102.

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Valence electron structures dependences of structural stability and properties of REX₃(RE=rare earth; X=In, Tl) and RE(In, Co)₃ alloys

Valence electron structures dependences of structural stability and properties of REX₃(RE=rare earth; X=In, Tl) and RE(In, Co)₃ alloys

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