Strain-induced specific orbital control in a Heusler alloy-based interfacial multiferroics

IF 8.6 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Npg Asia Materials Pub Date : 2024-01-10 DOI:10.1038/s41427-023-00524-6

Jun Okabayashi, Takamasa Usami, Amran Mahfudh Yatmeidhy, Yuichi Murakami, Yu Shiratsuchi, Ryoichi Nakatani, Yoshihiro Gohda, Kohei Hamaya

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Abstract

For the development of spintronic devices, the control of magnetization by a low electric field is necessary. The microscopic origin of manipulating spins relies on the control of orbital magnetic moments (morb) by strain; this is essential for the high performance magnetoelectric (ME) effect. Herein, electric-field induced X-ray magnetic circular dichroism (XMCD) is used to determine the changes in morb by piezoelectric strain and clarify the relationship between the strain and morb in an interfacial multiferroics system with a significant ME effect; the system consists of the Heusler alloy Co2FeSi on a ferroelectric Pb(Mg1/3Nb2/3)O3-PbTiO3 substrate. Element-specific investigations of the orbital states by operando XMCD and the local environment via extended X-ray absorption fine structure (EXAFS) analysis show that the modulation of only the Fe sites in Co2FeSi primarily contributes to the giant ME effect. The density functional theory calculations corroborate this finding, and the growth of the high index (422) plane in Co2FeSi results in a giant ME effect. These findings elucidate the element-specific orbital control using reversible strain, called the ‘orbital elastic effect,’ and can provide guidelines for material designs with a giant ME effect. Schematic illustrations of the changes in the magnetic anisotropy by an applied electric field (E) in the strain directions are displayed. Under an applied E, the piezoelectric stress in the ferroelectric PMN-PT could be introduced in the tensile and compressive directions using positive and negative bias voltages, respectively, resulting in the changes in the magnetic anisotropy in the Co2FeSi layer. The XMCD spectra of Fe and Co L-edges in Co2FeSi under applying E showed the line shape changes only in the Fe site, which corresponds to the changes of orbital magnetic moment in Fe, while that in Co remains unchanged.

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基于 Heusler 合金的界面多铁氧体中由应变引起的特定轨道控制

为了发展自旋电子器件，需要用低电场控制磁化强度。操纵自旋的微观起源依赖于应变对轨道磁矩的控制；这对于高性能磁电（ME）效应是必不可少的。本文利用电场诱导x射线磁圆二色性（XMCD）测定了压电应变对morb的影响，阐明了具有显著ME效应的界面多铁质体系中应变与morb的关系；该体系由Heusler合金Co2FeSi在铁电Pb(Mg1/3Nb2/3)O3-PbTiO3衬底上组成。通过扩展x射线吸收精细结构（EXAFS）分析和operando XMCD对轨道态的元素特异性研究表明，Co2FeSi中仅Fe位的调制是产生巨大ME效应的主要原因。密度泛函理论计算证实了这一发现，Co2FeSi中高指数（422）平面的生长导致了巨大的ME效应。这些发现阐明了使用可逆应变的元素特定轨道控制，称为“轨道弹性效应”，并且可以为具有巨大ME效应的材料设计提供指导。图中显示了外加电场(E)在应变方向上磁各向异性变化的示意图。在外加E的作用下，正偏置电压和负偏置电压分别在拉伸和压缩方向上引入铁电PMN-PT中的压电应力，导致Co2FeSi层的磁各向异性发生变化。在施加E的作用下，Co2FeSi中Fe和Co l边的XMCD谱显示，只有Fe位点的线形发生了变化，这对应于Fe中轨道磁矩的变化，而Co中的轨道磁矩保持不变。

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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来源期刊

Npg Asia Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

15.40

自引率

1.00%

发文量

审稿时长

2 months

期刊介绍： NPG Asia Materials is an open access, international journal that publishes peer-reviewed review and primary research articles in the field of materials sciences. The journal has a global outlook and reach, with a base in the Asia-Pacific region to reflect the significant and growing output of materials research from this area. The target audience for NPG Asia Materials is scientists and researchers involved in materials research, covering a wide range of disciplines including physical and chemical sciences, biotechnology, and nanotechnology. The journal particularly welcomes high-quality articles from rapidly advancing areas that bridge the gap between materials science and engineering, as well as the classical disciplines of physics, chemistry, and biology. NPG Asia Materials is abstracted/indexed in Journal Citation Reports/Science Edition Web of Knowledge, Google Scholar, Chemical Abstract Services, Scopus, Ulrichsweb (ProQuest), and Scirus.