Preparation and Electromagnetic Properties of Manganese Zinc Ferrite/Barium Ferrite Composite Materials

Quan Yuan; Wang Qun; Zhi Xue Qu; Zi Xin Gu; Tong Wu

doi:10.4028/www.scientific.net/KEM.519.215

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 519Preparation and Electromagnetic Properties of...

Preparation and Electromagnetic Properties of Manganese Zinc Ferrite/Barium Ferrite Composite Materials

Abstract:

Abstract: Manganese zinc ferrite/barium ferrite composite materials were prepared with various content of Z type barium ferrite (0, 10, 20 wt%) using solid state reaction method. The effect of the compositon on the microstructure and electromagnetic properties of the composites are investigated by means of X-ray diffraction, scanning electron microscope and impedance analyzer. The X-ray diffraction patterns reveal that W phase of barium ferrite instead of Z phase appears in the composite sintered as well as the spinel phase. Some small hexagonal grains were observed in the SEM images and the proportion increases with increasing content of barium ferrite. The cut-off frequencies of the composite systematically shift towards high frequency from 2.5 MHz to 32.6 MHz which is attributed to the increasing of W phase. The composites show a higher frequency for the maximum of the impedance as well as a higher value of the impedance at certain frequency which may be benefit for the application at GHz frequency range.

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Periodical:

Key Engineering Materials (Volume 519)

Pages:

215-219

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.519.215

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Online since:

July 2012

Authors:

Quan Yuan, Wang Qun, Zhi Xue Qu, Zi Xin Gu, Tong Wu

Keywords:

Composite Material, Electromagnetic Properties, Ferrite

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References

[1] Xu Chao, Lu Dianqing, Liu Xuedong, Xiong Yuanlu, Electromagnetic properties of NiCo ferrite prepared by the sol-gel self-combustion method, Electric Components and Materials. 3 (2010) 20-23.

Google Scholar

[2] Zhou Ji, Zhang Yaoxi, EMC and Countermeasure Component of EMI, Electric Component & Device Applications. 4 (2001) 1-4.

Google Scholar

[3] J.Azadmanjiri, Preparation of Mn-Zn ferrite nanoparticles from chemical sol-gel combustion method and the magnetic properties, Journal of Non-crystalline Solids. 44-46 (2007) 4170-4173.

DOI: 10.1016/j.jnoncrysol.2007.06.046

Google Scholar

[4] Liu Yapi, He Shijin, Development of High Frequency and High DC-Bias MnZn Frrite DMR50B Material, Journal of Magnetic Materials and Devices. 3 (2010) 36-41.

Google Scholar

[5] Chen Shichai, Luo Jun, Jia Lijun, Zhang Huaiwu, Electromagnetic Properties of PZT-NiCuZn Composite Materials, Journal of Magnetic Materials and Devices. 3 (2008) 34-38.

Google Scholar

[6] Zhong Hui, Zhang Huaiwu, Zhou Haitao, Magnetic Properties of BaTiO3-NiCuZn Composite Material, Journal of Magnetic Materials and Devices. 4 (2003) 10-12.

Google Scholar

[7] Huang Wanxia, Mao Jian, Wu Xing, Chen Jiazhao, Tu Mingjing, Study of Electromagnetic Wave Absorbency of Ferromagnetic/Ferroelectric Composite (Mn-Zn Ferrite/BaTiO3, Ni-Zn Ferrite/BaTiO3), Journal of Sichuan University (Engineering Science Edition). 6 (1998) 110-113.

DOI: 10.1109/elmagc.2002.1177500

Google Scholar

[8] Zhou Shaorong, Xiao Peiyi, Chen Jinqing, Tian Changsheng, Three-terminal Multilayer Ceramic EMI Filter, Electronic Components and Materials. 2 (2002) 22-24.

Google Scholar

[9] Gao Feng, Yang Zupei, Liu Xiangchun, Tian Changsheng, Phase Structrue and Dielectric Properties of Ferroelectrics and Ferrite Mixed Composites, Acta Materiae Copositae Sinica. 5 (2004) 22-27.

Google Scholar

[10] Feng Zekun, Li Haihua, He Huahui, Study on Z-type Hexagonal Ferrite Used in UHF Band, Advanced Ceramics. 2 (2002) 3-5.

Google Scholar

[11] Wang Yilin, Wu Wenjun, Mao Wendong, Zhao Meiyu, Effect of Doping on Crystalline Phases and Magnetic Properties of Z-Hexaferrite, Electronic Components and Materials. 5 (2002) 8-10.

Google Scholar

[12] R. D. Shannon, Revised Effective Ionic Radii and Systematic Studies of Interatomic Distances in Halides and Chalcogenides, Acta Crystallographica. A32 (1976) 751-767.

DOI: 10.1107/s0567739476001551

Google Scholar

[13] Wang Qi, Guan Jianguo, Liu Biao, Zhang Qingjie, Effect of the Preparation Technology on the Crystal Structure of Zn2-W type hexagonal ferrites, J. Functional Materials. 2 (2004) 164-168.

Google Scholar

[14] Wan Defu, Ma Xinglong, Magnetism Physics, Electronic Industry Press, Beijing, 1999.

Google Scholar

[15] Huang Xiaogu, Chen Jiao, Wang Lixi, Song Jie, Xu Naicen, Zhang Qitu, Electromagnetic properties and microwave absorbing behavior of (Zn0.3Co0.7)2-W type barium ferrites, Electronic Components and Materials. 3 (2010) 54-61.

Google Scholar