Influence of Rare Earth Yb3+ Dopant on the Spectroscopic Properties of Manganese Ferrite Nanoparticles

IF 0.8 4区 化学 Q4 SPECTROSCOPY
Sudha Gulati, Mansi Dhingra
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引用次数: 0

Abstract

A series of MnFe2–xYbxO4 powder nanoparticles (for x = 0, 0.025, 0.075, 0.1, and 0.2) of different crystallite sizes were synthesised using the co-precipitation method. The effect of Yb3+ dopant on the properties of manganese ferrite was characterised by X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FT-IR), Raman measurements, and photoluminescence spectroscopy (PL). The crystallite size and density of the samples have a cubic structure with an Fd3m space group. Their sizes and densities were found to be in the range of 24.8–34.7 nm and 5.07–5.49 g/cm3. FT-IR analysis indicates the presence of two absorption bands in the range 400–600 cm–1, which is a fingerprint region of ferrites. The v2 band (Fe–O stretching mode of the octahedral site) shifts towards the lower wavenumber, which confirms the occupancy of larger-size Yb3+ ions at the octahedral site. The Raman peaks were noted at 228, 295, 405, 502, and 634 cm–1 for undoped manganese ferrite. Based on Raman observations, it has been observed that Mn2+ ions exhibit a preference for occupying octahedral (B) sites by substituting Fe3+ ions. Additionally, rare earth ions have been preferentially observed to occupy octahedral sites. The primary cause for the displacement of Raman bands was ascribed predominantly to the greater radii of rare earth ions in comparison with Fe3+ and Mn2+ ions, and the shifting of the peaks indicates the presence of Yb3+ at the octahedral site. The PL spectrum shows emission at 560 nm with a rise in intensity with an increase in dopant Yb3+, which could be because of the incorporation of Yb3+ in the spinel structure, leading to radiative recombination in the yellow region of the electromagnetic spectrum.

稀土掺杂剂 Yb3+ 对纳米锰铁氧体光谱特性的影响
采用共沉淀法合成了一系列不同晶粒尺寸的 MnFe2-xYbxO4(x = 0、0.025、0.075、0.1 和 0.2)粉末纳米粒子。通过 X 射线衍射 (XRD)、傅立叶变换红外光谱 (FT-IR)、拉曼测量和光致发光光谱 (PL) 表征了掺杂 Yb3+ 对锰铁氧体性质的影响。样品的晶体尺寸和密度为立方结构,空间群为 Fd3m。它们的尺寸和密度范围分别为 24.8-34.7 纳米和 5.07-5.49 克/立方厘米。傅立叶变换红外分析表明,在 400-600 cm-1 范围内存在两条吸收带,这是铁氧体的指纹区。v2 波段(八面体位点的 Fe-O 伸展模式)向低波段移动,这证实了八面体位点存在较大尺寸的 Yb3+ 离子。未掺杂锰铁氧体的拉曼峰分别出现在 228、295、405、502 和 634 cm-1 处。根据拉曼观测结果,可以发现 Mn2+ 离子通过取代 Fe3+ 离子,表现出了占据八面体 (B) 位点的偏好。此外,还观察到稀土离子优先占据八面体位点。拉曼条带位移的主要原因是稀土离子的半径比 Fe3+ 和 Mn2+ 离子的半径大,而峰值的移动表明八面体位点上存在 Yb3+。聚光光谱显示,随着掺杂剂 Yb3+ 的增加,在 560 纳米处的发射强度会上升,这可能是因为尖晶石结构中掺入了 Yb3+,导致在电磁波谱的黄色区域发生辐射重组。
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来源期刊
CiteScore
1.30
自引率
14.30%
发文量
145
审稿时长
2.5 months
期刊介绍: Journal of Applied Spectroscopy reports on many key applications of spectroscopy in chemistry, physics, metallurgy, and biology. An increasing number of papers focus on the theory of lasers, as well as the tremendous potential for the practical applications of lasers in numerous fields and industries.
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