不同取代对镧掺杂锰钡六铁体光学性能的增强

IF 1.5 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

Advances in Condensed Matter Physics Pub Date : 2021-03-06 DOI:10.1155/2021/8849595

M. Alzaid

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引用次数: 7

摘要

钡六铁氧体磁性材料的磁导率和电阻率可用于磁性记录介质、计算机、电子器件、永磁体材料、通信器件等各种产品。本文研究了用共沉淀法合成稀土镧(La3+)掺杂锰的六铁体钡(Ba1−xLaxMnyFe12−yO19) (x = 0.02-0.10, y = 0.02-0.10)。强度峰随镧浓度的增加而增大，表明结晶度增强，晶粒尺寸增大。带隙能量随镧浓度的增加而逐渐减小。显微照片观察到，该材料基本上是由一些环或棒组成的，如纯六铁体钡中的La-Ma颗粒。在600°C时，由于热行为或浓度效应而出现了结块现象。结构研究是用x射线衍射、紫外、红外光谱和扫描电镜技术完成的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Enhancement in Optical Properties of Lanthanum-Doped Manganese Barium Hexaferrites under Different Substitutions

The permeability and electrical resistivity of barium hexaferrite magnetic materials can be used in various products such as magnetic recording media, computers, electronic devices, materials for permanent magnets, and communication devices. This work focuses on the synthesis of rare earth lanthanum (La3+)-doped manganese in barium hexaferrite (Ba1−xLaxMnyFe12−yO19) (x = 0.02–0.10 and y = 0.02–0.10) prepared by using the coprecipitation method. The intensity peak is increased with increasing the concentration of lanthanum, which shows the enhancement in the degree of crystallinity and increase in the size of crystallite. The band gap energy decreased gradually with the increase of concentration of lanthanum. The micrographs observed that the material is basically made up of some rings or rods such as particles in pure La-Ma in barium hexaferrite. The agglomeration was observed because of heat behavior at 600°C or may be concentration effect. The structural studies are done using X-ray diffraction, UV, FT-IR, and SEM techniques.

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来源期刊

Advances in Condensed Matter Physics PHYSICS, CONDENSED MATTER-

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Advances in Condensed Matter Physics publishes articles on the experimental and theoretical study of the physics of materials in solid, liquid, amorphous, and exotic states. Papers consider the quantum, classical, and statistical mechanics of materials; their structure, dynamics, and phase transitions; and their magnetic, electronic, thermal, and optical properties. Submission of original research, and focused review articles, is welcomed from researchers from across the entire condensed matter physics community.