Dielectric Properties of Three Perovskite Oxides Included in Three Types of Polymer Composites
DOI:
https://doi.org/10.56294/sctconf2024866Keywords:
Dielectric Constant, Loss Factor, Perovskite Ceramics, Composites, Communication TechnologyAbstract
Microwave dielectric double perovskite /polymer composites are materials that combine the flexibility of polymer matrices like epoxy, polyurethane, or silicone rubber with unique properties of double perovskite ceramics, such as Ba2ZnWO6, Ba2MgWO6, and Bi2Mo0,5W0,5O6. These complex oxide ceramics are synthesized using the solid-state reaction technique. The X-ray diffraction analysis (XRD) confirmed the formation of the double perovskite phase with well-defined crystal structures. Utilizing transmission/reflection measurements by a vector network analyzer (VNA) and double perovskite ceramics as filler materials in the polymer matrix, the impact of the complex oxide fillers on the composites' overall dielectric properties was fully measured. In particular, the dielectric properties of the resulting composites, specifically their dielectric loss and dielectric constant, were investigated within the wide frequency range of 4-8 GHz. Better dielectric characteristics, such as a high dielectric constant and a low loss factor, were demonstrated by Ba2ZnWO6, which made it a viable option for use in high-frequency circuits, microwave devices, energy storage components and communication technology. Furthermore, Competitive dielectric qualities were demonstrated by Ba2MgWO6 and Bi2Mo0,5W0,5O6. In addition, the results indicated improved dielectric characteristics, including dielectric constant and loss factor. The resulting composites not only have a lower cost and light weight than ceramics, but they also have a lot of potential uses in the microwave dielectric range. Furthermore, when compared to the other measured composites the Ba2ZnWO6/polymer composites demonstrated superior properties.
References
1. Youngs, I. J., G. C. Stevens, and A. S. Vaughan. "Trends in dielectrics research: an international review from 1980 to 2004." Journal of Physics D: Applied Physics 39, no. 7 (2006): 1267.
2. Pecht, Michael, Rakish Agarwal, F. Patrick McCluskey, Terrance J. Dishongh, Sirus Javadpour, and Rahul Mahajan. Electronic packaging materials and their properties. CRC press, 2017.
3. Chung, Deborah DL. Materials for electronic packaging. Elsevier, 1995.
4. Tummala, Rao R. "Ceramic and glass‐ceramic packaging in the 1990s." Journal of the American Ceramic Society 74, no. 5 (1991): 895-908.
5. Bolt, John D., Daniel P. Button, and Bruce A. Yost. "Ceramic-fiber—polymer composites for electronic substrates." Materials Science and Engineering: A 109 (1989): 207-211.
6. Subodh, G., C. Pavithran, P. Mohanan, and M. T. Sebastian. "PTFE/Sr2Ce2Ti5O16 polymer ceramic composites for electronic packaging applications." Journal of the European Ceramic Society 27, no. 8-9 (2007): 3039-3044.
7. Subodh G, Deepu V, Mohanan P and Sebastian M T 2009 Polym. Eng. Sci. 49 1218
8. Subodh, Ganesanpotti, Manoj Joseph, Pezholil Mohanan, and Mailadil Thomas Sebastian. "Low dielectric loss polytetrafluoroethylene/TeO2 polymer ceramic composites." Journal of the American Ceramic Society 90, no. 11 (2007): 3507-3511.
9. Khalyavin, D. D., Jiaping Han, A. M. R. Senos, and P. Q. Mantas. "Synthesis and dielectric properties of tungsten-based complex perovskites." Journal of materials research 18, no. 11 (2003): 2600-2607.
10. Rehman, Mehtab Ur, Qun Wang, and Yunfei Yu. "Electronic, Magnetic and Optical Properties of Double Perovskite Compounds: A First Principle Approach." Crystals 12, no. 11 (2022): 1597.
11. Zhao, Fei, Zhenxing Yue, Zhilun Gui, and Longtu Li. "Preparation, characterization and microwave dielectric properties of A2BWO6 (A= Sr, Ba; B= Co, Ni, Zn) double perovskite ceramics." Japanese journal of applied physics 44, no. 11R (2005): 8066.
12. Bian, J. J., K. Yan, and Y. F. Dong. "Microwave dielectric properties of A1− 3x/2Lax (Mg1/2W1/2) O3 (A= Ba, Sr, Ca; 0.0≤ x≤ 0.05) double perovskites." Materials Science and Engineering: B 147, no. 1 (2008): 27-34.
13. Zhou, Yuanyuan, Siqin Meng, Hongchao Wu, and Zhenxing Yue. "Microwave Dielectric Properties of Ba2Ca1− xSrxWO6Double Perovskites." Journal of the American Ceramic Society 94, no. 9 (2011): 2933-2938.
14. Nguyen, V. H., M. H. Hoang, H. P. Phan, T. Q. V. Hoang, and T. P. Vuong. "Measurement of complex permittivity by rectangular waveguide method with simple specimen preparation." In 2014 International Conference on Advanced Technologies for Communications (ATC 2014), pp. 397-400. IEEE, 2014.
15. Mabhouti, Kh, M. Karamirad, P. Norouzzadeh, M. M. Golzan, and R. Naderali. "Measurement of nickel doped zinc oxide NPs resonance frequencies and electromagnetic properties in X-Band." Physica B: Condensed Matter 602 (2021): 412532.
16. Vicente, Alexandre Natã, Gustavo Maciulis Dip, and Cynthia Junqueira. "The step by step development of NRW method." In 2011 SBMO/IEEE MTT-S International Microwave and Optoelectronics Conference (IMOC 2011), pp. 738-742. IEEE, 2011.
17. Zhang, Li, Zhen Xing Yue, and Long Tu Li. "Ceramic-polymer composites with low dielectric loss for microwave antennas and wireless sensors." Key Engineering Materials 655 (2015): 153-158.
18. Subodh, G., V. Deepu, P. Mohanan, and M. T. Sebastian. "Dielectric response of Sr2Ce2Ti5O15 ceramics reinforced high density polyethylene." Journal of Physics D: Applied Physics 42, no. 22 (2009): 225501.
Published
Issue
Section
License
Copyright (c) 2024 Lamees S. Faeq, Saad B. H. Farid, Fadhil A. Hashim (Author)
This work is licensed under a Creative Commons Attribution 4.0 International License.
The article is distributed under the Creative Commons Attribution 4.0 License. Unless otherwise stated, associated published material is distributed under the same licence.
