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用于确定结构和光学特性的锰和锌掺杂镍铁氧体纳米粉末的乌尔巴赫能量和克拉默斯-克勒尼希研究

Study of Urbach energy and Kramers-Kronig on Mn and Zn doped NiFeO ferrite nanopowder for the determination of structural and optical characteristics.

作者信息

Nazari N, Golzan M M, Mabhouti Kh

机构信息

Department of Physics, Faculty of Sciences, Urmia University, Urmia, Iran.

出版信息

Sci Rep. 2024 Mar 17;14(1):6407. doi: 10.1038/s41598-024-57045-7.

DOI:10.1038/s41598-024-57045-7
PMID:38494547
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10944846/
Abstract

MNiFeO spinel ferrite (M = Mn, Zn, and x = 0, 0.05) has been successfully synthesized by co-precipitation technique with hydrazine hydrate reduction agent (instead of NaOH) and Ethylene glycol surfactant. The XRD spectra of the samples illustrated high crystallinity. The structural characterization of pure and doped fcc NiFeO were calculated by Scherrer, Modified Scherrer, Williamson-Hall, and SSP methods. In comparison of several methods, the Scherrer method is unreasonable method and W-H method has an acceptable range and can calculate both < L > and strain without restriction. The specific surface area in Zn-doped increased, demonstrate increment of adsorption properties in Ni ferrite structure. TEM images revealed the shape of grains is spherical, cubic, and irregular, with a grain size in the range of 35-65 nm. Hysteresis loops illustrated the magnetic behavior of samples. From the reflectance data, the band gap energies were estimated at 1.984, 1.954, and 1.973 eV for un-doped, Mn, and Zn-doped NiFeO respectively (red shift). The almost low value of Urbach energy for pure, Mn, and Zn -doped NiFeO indicates low structural disorder, which can approve the high crystallinity of samples. Direct band gap energy (E), refractive index, and extinction coefficient were estimated by the Kramers-Kronig method with linear optical evaluations. The E by K-K method is in good agreement with the E by Kubelka-Munk function.

摘要

通过水合肼还原剂(代替氢氧化钠)和乙二醇表面活性剂的共沉淀技术成功合成了MNiFeO尖晶石铁氧体(M = Mn、Zn,x = 0、0.05)。样品的XRD光谱显示出高结晶度。采用谢乐法、改进谢乐法、威廉姆森-霍尔法和SSP法计算了纯相和掺杂的面心立方NiFeO的结构特征。在几种方法的比较中,谢乐法是不合理的方法,而W-H法有可接受的范围,并且可以不受限制地计算和应变。锌掺杂后比表面积增加,表明镍铁氧体结构中吸附性能增强。TEM图像显示晶粒形状为球形、立方体形和不规则形,粒径范围为35-65nm。磁滞回线说明了样品的磁行为。根据反射率数据,未掺杂、Mn掺杂和Zn掺杂的NiFeO的带隙能量分别估计为1.984、1.954和1.973eV(红移)。纯相、Mn掺杂和Zn掺杂的NiFeO的乌尔巴赫能量几乎较低,表明结构无序度较低,这可以证明样品具有高结晶度。通过线性光学评估的克拉默斯-克勒尼希方法估计了直接带隙能量(E)、折射率和消光系数。K-K方法得到的E与库贝尔卡-蒙克函数得到的E吻合良好。

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