Investigations on the enhancement of thermomagnetic properties in Fe2.4Ga0.6O4

IF 1.3 4区材料科学 Q3 CRYSTALLOGRAPHY Phase Transitions Pub Date : 2022-12-31 DOI:10.1080/01411594.2022.2159404

K. Rećko, M. Orzechowska, W. Olszewski, A. Beskrovnyy, M. Biernacka, U. Klekotka, A. Miaskowski, K. Szymański

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引用次数: 1

Abstract

ABSTRACT The structural, magnetic and calorimetric properties of Fe2.4Ga0.6O4 nanoferrite have been investigated. X-ray and neutron diffraction coupled analyses using Rietveld refinements have shown that the samples under investigation, obtained by different bottom-up methods, crystalize with a cubic structure in the space group (N° 227). The Ga3+ ions preferentially occupying the tetrahedral sublattice of the inverse spinel partly screen the dipole–dipole interactions and lead to the reduction of the magnetic response of Fe3+ ones. Calorimetric measurements confirm that the nanosized Fe2.4Ga0.6O4 system weakly agglomerates and simultaneously collect and release optimal amount of heat under the influence of an alternating magnetic field with the 15.3 kA/m of maximum magnetic field strength and 532 kHz of frequency. The values of the specific absorption coefficients obtained for gallium ferrites, similar to those typical for cobalt ferrites used commercially in biomedicine, together with very low superparamagnetic blocking temperature validated by Mössbauer spectroscopy analysis, make the system an attractive therapeutic material.

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Fe2.4Ga0.6O4增强热磁性能的研究

研究了Fe2.4Ga0.6O4纳米铁氧体的结构、磁性和量热性能。使用Rietveld精炼的X射线和中子衍射耦合分析表明，通过不同的自下而上的方法获得的研究中的样品在空间群（N°227）中以立方结构结晶。Ga3+离子优先占据反尖晶石的四面体子晶格，部分屏蔽了偶极-偶极相互作用，导致Fe3+离子的磁响应降低。热量测量证实，纳米尺寸的Fe2.4Ga0.6O4系统在15.3 kA/m的最大磁场强度和532 kHz的频率。镓铁氧体获得的比吸收系数的值与生物医学中商业使用的钴铁氧体的典型值相似，加上通过穆斯堡尔谱分析验证的非常低的超顺磁阻断温度，使该系统成为一种有吸引力的治疗材料。

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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.