合成温度对Dy取代镍纳米铁氧体结构和磁性能的影响

IF 1.3 4区材料科学 Q3 CRYSTALLOGRAPHY

Phase Transitions Pub Date : 2023-06-27 DOI:10.1080/01411594.2023.2228968

Vikas S. Shinde, Ravindra N. Chikhale

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引用次数: 0

摘要

摘要采用柠檬酸溶胶-凝胶自燃烧法合成了Dy取代的NiFe1.95Dy0.05O4铁氧体纳米颗粒。样品在400°C、700°C和900°C的温度下烧结。X射线衍射测量清楚地表明，对于所有烧结样品，形成了立方尖晶石结构以及小的正铁氧体相。晶粒尺寸从17.79增加到39.36 nm，而晶粒尺寸从50.70增加 nm至83.05 nm。观察到晶格参数和晶格体积随着烧结温度的升高而减小。红外光谱证实了制备样品的尖晶石铁氧体结构。随着烧结温度的升高，饱和磁化强度从25.80 emu/gm增加到49.48 emu/gm，矫顽力值从207.95 Oe降低到165.43 Oe。随着烧结温度的升高，饱和磁化强度的增加和矫顽力的降低使合成的纳米颗粒适用于高密度数据存储器件。

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Influence of synthetic temperature on structural and magnetic properties of Dy substituted Ni nanoferrite

ABSTRACT Dy substituted Ni ferrite nanoparticles with composition NiFe1.95Dy0.05O4 were synthesized by using the citric acid sol–gel auto combustion method. The samples were sintered at temperatures of 400°C, 700°C, and 900°C. The X-ray diffraction measurements clearly showed the formation of a cubic spinel structure along with a small orthoferrite phase for all the sintered samples. The crystallite size increases from 17.79 to 39.36 nm while the grain size increases from 50.70 nm to 83.05 nm. The lattice parameter and lattice volume decrease with increasing sintering temperature was observed. The Spinel ferrite structure of prepared samples has been confirmed from FTIR spectra. With increasing sintering temperature saturation magnetization increases from 25.80 emu/gm to 49.48 emu/gm while the coercivity value decreases from 207.95 Oe to 165.43 Oe. Increasing saturation magnetization and decreasing coercivity values with increasing sintering temperature make the synthesized nanoparticles suitable for high-density data storage devices.

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来源期刊

Phase Transitions 物理-晶体学

CiteScore

3.00

自引率

6.20%

发文量

审稿时长

1.4 months

期刊介绍： Phase Transitions is the only journal devoted exclusively to this important subject. It provides a focus for papers on most aspects of phase transitions in condensed matter. Although emphasis is placed primarily on experimental work, theoretical papers are welcome if they have some bearing on experimental results. The areas of interest include: -structural phase transitions (ferroelectric, ferroelastic, multiferroic, order-disorder, Jahn-Teller, etc.) under a range of external parameters (temperature, pressure, strain, electric/magnetic fields, etc.) -geophysical phase transitions -metal-insulator phase transitions -superconducting and superfluid transitions -magnetic phase transitions -critical phenomena and physical properties at phase transitions -liquid crystals -technological applications of phase transitions -quantum phase transitions Phase Transitions publishes both research papers and invited articles devoted to special topics. Major review papers are particularly welcome. A further emphasis of the journal is the publication of a selected number of small workshops, which are at the forefront of their field.