High-throughput evaluation of half-metallicity of Co₂MnSi Heusler alloys using composition-spread films and spin-integrated hard X-ray photoelectron spectroscopy.

IF 7.4 3区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Science and Technology of Advanced Materials Pub Date : 2025-01-07 eCollection Date: 2025-01-01 DOI:10.1080/14686996.2024.2439781

Ryo Toyama, Shunsuke Tsuda, Yuma Iwasaki, Thang Dinh Phan, Susumu Yamamoto, Hiroyuki Yamane, Koichiro Yaji, Yuya Sakuraba

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引用次数: 0

Abstract

We demonstrate high-throughput evaluation of the half-metallicity of Co₂MnSi Heusler alloys by spin-integrated hard X-ray photoelectron spectroscopy (HAXPES) of composition-spread films performed with high-brilliance synchrotron radiation at NanoTerasu, which identifies the optimum composition showing the best half-metallicity. Co_75-x Mn _x Si₂₅ composition-spread thin films for x = 10-40% with a thickness of 30 nm are fabricated on MgO(100) substrates using combinatorial sputtering technique. The L2₁-ordering and (001)-oriented epitaxial growth of Co₂MnSi are confirmed by X-ray diffraction for x = 18-40%. The valence band HAXPES spectra exhibit a systematic compositional dependence and the smallest photoemission intensity at the Fermi level (E _F) for a slightly Mn-rich composition of x = 27%. The density of states (DOS) for L2₁-ordered Co₂MnSi with different Mn compositions obtained from first-principles calculation also show the smallest total DOS at E _F for x = 27% because of the formation of a clear half-metallic gap in the minority spin channel and the less localized d-states in the majority spin channel, indicating the best half-metallic nature of this composition. Our experimental results demonstrate that high-throughput evaluation of half-metallicity is possible even with spin-integrated HAXPES by capturing systematic changes in the electronic structures through the measurements on the composition-spread film. Moreover, the anisotropic magnetoresistance (AMR) of the composition-spread film is measured for electric current directions along the [110] and [100] of Co₂MnSi. Previous studies indicated that a larger negative AMR ratio is a signature of a higher spin polarization. The largest negative AMR ratio is observed for x = 27% for both current directions, which also supports the best half-metallicity for this off-stoichiometric composition.

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Co2MnSi Heusler合金半金属丰度的高通量评价——基于成分扩散膜和自旋集成硬x射线光电子能谱。

在NanoTerasu高亮度同步辐射下，利用自旋积分硬x射线光电子能谱（HAXPES）对Co2MnSi Heusler合金的半金属丰度进行了高通量评价，确定了具有最佳半金属丰度的最佳成分。采用组合溅射技术在MgO（100）衬底上制备了Co75-x Mn x Si25复合薄膜，厚度为30 nm，厚度为x = 10-40%。x射线衍射证实了Co2MnSi在x = 18-40%时的l21有序生长和（001）取向外延生长。价带HAXPES光谱显示出系统的组分依赖性，并且对于略富mn的成分（x = 27%），在费米能级上具有最小的光电发射强度（E F）。由第一性原理计算得到的不同Mn组分的l21有序Co2MnSi的态密度（DOS）也表明，当x = 27%时，由于在少数自旋通道中形成了明显的半金属间隙，而在大多数自旋通道中形成了较少的局域化d态，所以总DOS最小，表明该成分具有最佳的半金属性质。我们的实验结果表明，即使使用自旋集成HAXPES，也可以通过测量成分扩散膜来捕获电子结构的系统变化，从而实现对半金属丰度的高通量评估。此外，沿着Co2MnSi的[110]和[100]电流方向测量了复合膜的各向异性磁阻（AMR）。以往的研究表明，较大的负AMR比是高自旋极化的标志。在两个电流方向上，x = 27%时观察到最大的负AMR比，这也支持了这种非化学计量成分的最佳半金属性。

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

Science and Technology of Advanced Materials 工程技术-材料科学：综合

CiteScore

10.60

自引率

3.60%

发文量

审稿时长

4.8 months

期刊介绍： Science and Technology of Advanced Materials (STAM) is a leading open access, international journal for outstanding research articles across all aspects of materials science. Our audience is the international community across the disciplines of materials science, physics, chemistry, biology as well as engineering. The journal covers a broad spectrum of topics including functional and structural materials, synthesis and processing, theoretical analyses, characterization and properties of materials. Emphasis is placed on the interdisciplinary nature of materials science and issues at the forefront of the field, such as energy and environmental issues, as well as medical and bioengineering applications. Of particular interest are research papers on the following topics: Materials informatics and materials genomics Materials for 3D printing and additive manufacturing Nanostructured/nanoscale materials and nanodevices Bio-inspired, biomedical, and biological materials; nanomedicine, and novel technologies for clinical and medical applications Materials for energy and environment, next-generation photovoltaics, and green technologies Advanced structural materials, materials for extreme conditions.