Structural, magnetic, optical, and electronic properties of vanadium-doped barium hexaferrite nanoparticles: Experimental and DFT approaches

IF 5.1 2区 材料科学 Q1 MATERIALS SCIENCE, CERAMICS
Aref Besharat, Seyedeh Mansoureh Hashemi, Esmaeil Mohebbi, Saeed Hasani
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Abstract

Vanadium-doped barium hexaferrite with a nanostructure is a highly valuable material in various technological fields, such as electronics, permanent magnets, and sensors. The Ba1-xFe12-xVxO19 (x = 0, 0.02, 0.04, 0.06, 0.08, and 0.1) nanoparticles derived from the aqueous solutions containing Fe:Ba molar ratio of 10:1 through the sol-gel auto-combustion method. Computational study was also performed using the first-principles density functional theory (DFT) approach. Crystal structure optimization, band structure, and density of states (DOS) calculations were conducted by CASTEP code. The variation of the structural, magnetic, optical, morphological, and electronic properties of V5+-doped barium hexaferrite was investigated. The XRD analysis combined with the Rietveld refinement showed the hexagonal structure of M-type barium ferrite (BaM), confirmed by the FT-IR analysis. The morphology of BaM nanoparticles was studied by the FE-SEM and TEM micrographs. In addition, magnetic and optical properties were analyzed through VSM and UV–Vis analysis. Crystallite size was found to be highly effective in tuning the coercivity and optical band gap of barium hexaferrites, which varied, respectively, from 3.24 to 4.83 kOe, and 2.69–3.69 eV. Magnetic results showed that several variables like cations distribution, lattice strain, and hematite secondary phase affected the nanoparticles’ magnetization. The DFT simulation results showed a sharp reduction of electronic band gap energy whether V takes the position of Ba or Fe (from 1.10 eV in undoped to 0.64 and 0.14 eV in doped structures). The projected density of states (PDOS) calculations demonstrated that the d orbitals of V and Ba mainly contribute to the valence band maximum (VBM) and conduction band minimum (CBM), respectively.
掺钒六铁钡纳米粒子的结构、磁性、光学和电子特性:实验和 DFT 方法
具有纳米结构的掺钒六价钡铁在电子、永磁体和传感器等多个技术领域都是一种非常有价值的材料。Ba1-xFe12-xVxO19 (x = 0、0.02、0.04、0.06、0.08 和 0.1)纳米粒子是通过溶胶-凝胶自燃烧法从含铁:钡摩尔比为 10:1 的水溶液中获得的。计算研究还采用了第一原理密度泛函理论(DFT)方法。利用 CASTEP 代码进行了晶体结构优化、能带结构和状态密度 (DOS) 计算。研究了掺杂 V5+ 的六价钡铁氧体的结构、磁性、光学、形貌和电子特性的变化。XRD 分析结合 Rietveld 精炼显示了 M 型钡铁氧体(BaM)的六方结构,并得到了 FT-IR 分析的证实。通过 FE-SEM 和 TEM 显微照片研究了 BaM 纳米颗粒的形态。此外,还通过 VSM 和 UV-Vis 分析仪分析了磁性和光学特性。研究发现,晶体尺寸对调整六价钡的矫顽力和光带隙非常有效,其变化范围分别为 3.24 至 4.83 kOe 和 2.69 至 3.69 eV。磁性结果表明,阳离子分布、晶格应变和赤铁矿次生相等几个变量都会影响纳米粒子的磁化。DFT 模拟结果表明,无论 V 位于 Ba 还是 Fe 的位置,电子带隙能都会急剧下降(从未掺杂结构中的 1.10 eV 降至掺杂结构中的 0.64 和 0.14 eV)。投影状态密度(PDOS)计算表明,V 和 Ba 的 d 轨道分别对价带最大值(VBM)和导带最小值(CBM)做出了主要贡献。
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来源期刊
Ceramics International
Ceramics International 工程技术-材料科学:硅酸盐
CiteScore
9.40
自引率
15.40%
发文量
4558
审稿时长
25 days
期刊介绍: Ceramics International covers the science of advanced ceramic materials. The journal encourages contributions that demonstrate how an understanding of the basic chemical and physical phenomena may direct materials design and stimulate ideas for new or improved processing techniques, in order to obtain materials with desired structural features and properties. Ceramics International covers oxide and non-oxide ceramics, functional glasses, glass ceramics, amorphous inorganic non-metallic materials (and their combinations with metal and organic materials), in the form of particulates, dense or porous bodies, thin/thick films and laminated, graded and composite structures. Process related topics such as ceramic-ceramic joints or joining ceramics with dissimilar materials, as well as surface finishing and conditioning are also covered. Besides traditional processing techniques, manufacturing routes of interest include innovative procedures benefiting from externally applied stresses, electromagnetic fields and energetic beams, as well as top-down and self-assembly nanotechnology approaches. In addition, the journal welcomes submissions on bio-inspired and bio-enabled materials designs, experimentally validated multi scale modelling and simulation for materials design, and the use of the most advanced chemical and physical characterization techniques of structure, properties and behaviour. Technologically relevant low-dimensional systems are a particular focus of Ceramics International. These include 0, 1 and 2-D nanomaterials (also covering CNTs, graphene and related materials, and diamond-like carbons), their nanocomposites, as well as nano-hybrids and hierarchical multifunctional nanostructures that might integrate molecular, biological and electronic components.
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