Role of Mg substitution in modulating defect-mediated magnetism and mechanical strength of Zn0.95Co0.05O systems

IF 3.2 4区材料科学 Q2 MATERIALS SCIENCE, CERAMICS

Journal of Sol-Gel Science and Technology Pub Date : 2025-07-31 DOI:10.1007/s10971-025-06882-7

E. Asikuzun, G. Yildirim, A. S. Ertürk, O. Ozturk, T. Seydioglu, C. Terzioglu

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Abstract

This study investigates the structural, magnetic, and mechanical modifications induced by partial Mg/Zn substitution in Zn_0.95Co_0.05O diluted magnetic semiconductor (DMS) systems prepared by the sol-gel method. A combination of X-ray diffraction (XRD), scanning electron microscopy (SEM), vibrating sample magnetometry (VSM), and Vickers microhardness (H_v) testing is employed to assess the impact of Mg incorporation. Experimental and computational results confirm the successful substitution of Mg²⁺ ions into the ZnCoO lattice without forming secondary phases. XRD analyses reveal a slight reduction in crystallite size, varying from 37.62 nm to 36.48 nm, attributable to the differences in ionic radius and electronegativity between Mg²⁺ and Zn²⁺ ions. Mg addition enhances crystallinity, interface state formation, and atomic-scale interactions, while promoting quantum confinement effects. SEM observations indicate that Mg/Zn substitution significantly influences particle size, surface morphology, and oxide layer thickness. Increasing Mg content improves grain coupling and surface uniformity through strengthened interfacial interactions. Microhardness results show that Mg incorporation improves mechanical stability by limiting crack propagation, enhancing grain boundary couplings, and minimizing stored internal strain energy. Magnetic measurements indicate that all samples exhibit predominantly paramagnetic behavior with weak ferromagnetic features emerging at low temperatures. Low-temperature magnetization is attributed to defect-mediated ferromagnetic coupling, whereas high-temperature behavior follows Curie–Weiss paramagnetism. The Mg/Zn substitution alters electronic structure and oxygen vacancy distribution, modulating exchange interactions. Small coercivity values (230 Oe in ZFC and 570 Oe in FC) and vertical M–H loop shifts at 5 K suggest diluted antiferromagnetism rather than conventional exchange bias effects. Additionally, creep analysis from loading–unloading curves confirms that increasing Mg content lowers the creep rate, with the ZnO: Mg (5%) sample exhibiting the best mechanical resilience. In conclusion, Mg substitution significantly enhances the structural, magnetic, and mechanical performance of ZnCoO matrices, making them more favorable for controlled paramagnetic applications than room-temperature spintronic technologies.

Graphical Abstract

Fundamental Structural Properties of Zn_0.95-xMg_xCo_0.05O DMS structure.

Abstract Image

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Mg取代对Zn0.95Co0.05O缺陷磁性和机械强度的调节作用

本文研究了用溶胶-凝胶法制备的Zn0.95Co0.05O稀释磁性半导体（DMS）体系中Mg/Zn部分取代引起的结构、磁性和力学修饰。采用x射线衍射（XRD）、扫描电镜（SEM）、振动样品磁强计（VSM）和维氏显微硬度（Hv）测试等方法对Mg掺入的影响进行了评价。实验和计算结果证实，Mg 2 +离子成功地取代了ZnCoO晶格，而没有形成二次相。XRD分析显示，由于Mg 2 +和Zn 2 +离子半径和电负性的差异，晶体尺寸略有减小，从37.62 nm到36.48 nm不等。Mg的加入增强了结晶度、界面态的形成和原子尺度的相互作用，同时促进了量子约束效应。SEM观察表明，Mg/Zn取代显著影响颗粒尺寸、表面形貌和氧化层厚度。Mg含量的增加通过增强界面相互作用改善了晶粒耦合和表面均匀性。显微硬度结果表明，Mg的掺入通过限制裂纹扩展、增强晶界耦合和最小化存储的内部应变能来提高材料的力学稳定性。磁性测量表明，所有样品都表现出主要的顺磁性行为，在低温下出现弱铁磁性特征。低温磁化归因于缺陷介导的铁磁耦合，而高温行为遵循居里-魏斯顺磁性。Mg/Zn取代改变了电子结构和氧空位分布，调节了交换作用。较小的矫顽力值（ZFC为230 Oe， FC为570 Oe）和5k时M-H环的垂直位移表明反铁磁性被稀释，而不是传统的交换偏置效应。此外，加载-卸载曲线的蠕变分析证实，Mg含量的增加降低了蠕变速率，其中ZnO: Mg（5%）的试样表现出最好的机械回弹性。综上所述，Mg取代显著提高了ZnCoO矩阵的结构、磁性和力学性能，使其比室温自旋电子技术更有利于控制顺磁性的应用。Zn0.95-xMgxCo0.05O DMS结构的基本结构性质。

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来源期刊

Journal of Sol-Gel Science and Technology 工程技术-材料科学：硅酸盐

CiteScore

4.70

自引率

4.00%

发文量

280

审稿时长

2.1 months

期刊介绍： The primary objective of the Journal of Sol-Gel Science and Technology (JSST), the official journal of the International Sol-Gel Society, is to provide an international forum for the dissemination of scientific, technological, and general knowledge about materials processed by chemical nanotechnologies known as the "sol-gel" process. The materials of interest include gels, gel-derived glasses, ceramics in form of nano- and micro-powders, bulk, fibres, thin films and coatings as well as more recent materials such as hybrid organic-inorganic materials and composites. Such materials exhibit a wide range of optical, electronic, magnetic, chemical, environmental, and biomedical properties and functionalities. Methods for producing sol-gel-derived materials and the industrial uses of these materials are also of great interest.