Tri-axial magnetic alignment and magnetic anisotropies in misfit-layered calcium-based cobaltites doped with rare-earth ions

IF 2.9 Q1 MATERIALS SCIENCE, CERAMICS Open Ceramics Pub Date : 2024-10-16 DOI:10.1016/j.oceram.2024.100697

Walid Bin Ali, Shintaro Adachi, Fumiko Kimura, Shigeru Horii

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Abstract

In this study, we introduce an original method for quantifying tri-axial magnetic anisotropy in [Ca₂CoO_3-δ]_0.62CoO₂, and its rare earth (RE)-doped variants, [(Ca_1-xRE_x)₂CoO_3-δ]_0.62CoO₂, utilizing a modulated rotating magnetic field of 10 T. Our findings reveal a significant correlation between the magnetic anisotropy and local structure of RE ions, particularly bond lengths and coordination numbers, which influence the magnetization axes of these magnetically aligned powders. We introduce an analytical methodology employing linear equations to calculate the magnetic susceptibilities along distinct crystallographic axes, enabling the prediction of tri-axial magnetic anisotropies at elevated concentrations of Er ions. This research not only advances our understanding of magnetic anisotropy control but also paves the way for the successful fabrication of triaxially-aligned ceramics using magneto-science techniques.

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掺杂稀土离子的错位层状钙基钴酸盐的三轴磁力排列和磁各向异性

在本研究中，我们介绍了一种利用 10 T 调制旋转磁场量化[Ca2CoO3-δ]0.62CoO2 及其掺杂稀土 (RE) 的变体[(Ca1-xREx)2CoO3-δ]0.62CoO2 的三轴磁各向异性的独创方法。我们的研究结果表明，磁各向异性与 RE 离子的局部结构（尤其是键长和配位数）之间存在着显著的相关性，而键长和配位数会影响这些磁性排列粉末的磁化轴。我们引入了一种分析方法，利用线性方程计算沿不同结晶轴的磁感应强度，从而能够预测高浓度铒离子的三轴磁各向异性。这项研究不仅加深了我们对磁各向异性控制的理解，还为利用磁科学技术成功制造三轴排列陶瓷铺平了道路。

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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