Fabrication of Cerium Doped Nickel-Cobalt Ferrite by Co-Precipitation Method

Journal of Materials and Physical Sciences Pub Date : 2020-06-30 DOI:10.52131/jmps.2020.0101.0004

Saira Yasmeen, H. U. H. K. Khan Asghar, Z. A. Gilani, Muhammad Khalid

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引用次数: 1

Abstract

In the modern world researchers caught the attraction towards spinal ferrites. The current work is based on spinel ferrites having formula Ni0.5Co0.5CexFe2-xO4 where (x = 0.0, 0.05, 0.1, 0.15, 0.2) Prepared by co-precipitation method. The confirmation of spinal ferrite structure was done through XRD analysis. The crystallite size was found to be in the range of 8 to 11 nm. Lattice perimeter is observe to obey the increasing trend due to replacement of larger ionic radii of cerium with smaller ionic radii of iron. Koop's phenomenological theory, Maxwell–Wagner interfacial polarization and Vegard’s law is used to explain the behavior of lattice constant. The electrical properties of prepared ferrites were revealed by impedance analyzer. Various parameters like real and imaginary parts of dialectic constant, impedance and modulus was determined. In the frequency range of 1 to 3 GHz the detailed electrical inspection was done. During the electrode polarization the effect of grains on the increasing substitution of cerium was analyzed through real and imaginary parts of electrical modulus M' and M". In the frequency range of 3 GHz the value of M' is 2.1934 × 10-1 to 2.6581 × 10-1 and the value of M" is from 4.67 × 10-3 to 3.538 × 10-3. AC conductivity spectra shows a non-Debye relaxation behavior and it dependents of conductivity on frequency. The observed dielectric constant, dialectic loss and tangent loss are found to be decreasing with the increase in frequency. The investigation shows that real and imaginary impedance Z' and Z" was found to be decreasing on lower frequencies and on higher frequencies all the curves merge with each other. The value of Z' and Z" at 3GHz frequency is in the range of 8.02 × 10-3 to 0.6073 and 3.7641 × 101 to 4.5617 ×101 respectively. Increase in frequency increases the AC conductivity. The applications of prepared nanoparticles are suggested in high frequency devices because of the splendid dielectric properties of these particles.

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共沉淀法制备掺铈镍钴铁氧体

在现代世界，研究人员抓住了脊椎铁氧体的吸引力。目前的工作是基于共沉淀法制备的尖晶石铁素体，其公式为ni0.5 co0.5 5cexfe2 - xo4 (x = 0.0, 0.05, 0.1, 0.15, 0.2)。通过XRD分析证实了脊状铁氧体的结构。晶粒尺寸在8 ~ 11 nm之间。由于较大离子半径的铈被较小离子半径的铁取代，晶格周长呈增大趋势。用库普的现象学理论、麦克斯韦-瓦格纳界面极化和维加德定律解释了晶格常数的行为。用阻抗分析仪测定了制备的铁氧体的电学性能。确定了辩证法常数、阻抗和模量的实部和虚部等参数。在1至3 GHz的频率范围内进行了详细的电气检查。通过电模量M′和M”的实部和虚部分析了电极极化过程中晶粒对铈取代量增加的影响。在3ghz频率范围内，M′值为2.1934 × 10-1 ~ 2.6581 × 10-1, M′值为4.67 × 10-3 ~ 3.538 × 10-3。交流电导率谱表现出非德拜弛豫行为，且与频率有关。观测到的介电常数、辩证法损耗和正切损耗随频率的增加而减小。研究表明，实阻抗和虚阻抗Z′和Z′在低频处呈减小趋势，在高频处曲线完全重合。在3GHz频率下，Z′和Z”的取值范围分别为8.02 × 10-3 ~ 0.6073和3.7641 ×101 ~ 4.5617 ×101。频率的增加会增加交流电导率。制备的纳米颗粒具有优异的介电性能，在高频器件中具有广泛的应用前景。

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Journal of Materials and Physical Sciences

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