Aims & Scope | Editorial Board| Open Access | Subscription Info. | KCI Impact Factor | Contact us
Archives | Search

Original Article

Ultra-high Temperature EM Wave Absorption Behavior for Ceramic/Sendust-aluminosilicate Composite in X-band
Kwang-Sik Choi^*, Dongyoung Sim^**, Wonwoo Choi^**, Joon-Hyung Shin^**, Young-Woo Nam^**†
* School of Mechanical and Aerospace Engineering, Gyeongsang National University and Korea Aerospace Industries, Ltd.
** School of Mechanical and Aerospace Engineering, Gyeongsang National University
X-Band 영역에서의 세라믹/샌더스트-알루미노실리케이트 복합재의 초고온 전자파 흡수 거동
최광식^* · 심동영^** · 최원우^** · 신준형^** · 남영우^**†
This article is an open access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

References

1. Rao, G.A., and Mahulikar, S.P., “Integrated Review of Stealth Technology and Its Role in Airpower”, Aeronautical Journal, Vol. 106, No. 1066, 2002, pp. 629-642.
2. Yang, Z., Luo, F., Sun, M., Xu, J., Zhou, W., Qing, Y., Zhu, D., and Huang, Z., “Design and Reflectivity Analysis of High Temperature Wave-absorbing Coatings with Circular Periodic Structure”, Materials Letters, Vol. 151, 2015, pp. 109-111.
3. Wan, F., Luo, F., Zhou, Y., Zhou, W., and Zhu, D., “A Glass Coating for SiC Fiber Reinforced Aluminum Phosphate Matrix (SiC_f/AlPO₄) Composites for High-temperature Absorbing Wave Applications,” Surface and Coatings Technology, Vol. 264, 2015, pp. 9-16.
4. Wang, J., Zhou, W., Luo, F., Zhu, D., and Qing, Y., “Dielectric and Microwave Absorbing Properties of Quartz Fiber/amorphous Carbon/polyimide Composites at Elevated Temperature,” Journal of Nanoscience and Nanotechnology, Vol. 17, No. 6, 2017, pp. 3751-3758.
5. Tian, H., Liu, H.T., and Cheng, H.F., “A High-temperature Radar Absorbing Structure: Design, Fabrication, and Characterization,” Composites Science and Technology, Vol. 90, 2014, pp. 202-208.
6. Song, H., Zhou, W., Luo, F., Huang, Z., Qing, Y., Chen, M., and Mu, Y., “Temperature Dependence of Dielectric Properties of SiC_f/PyC/SiC Composites,” Materials Science and Engineering: B, Vol. 195, 2015, pp. 12-19.
7. Baskey, H.B., Kumar, D., Shami, T.C., Kumar, R., Kumar, S., Dixit, A.K., and Prasad, N.E., “In-situ High-temperature Electromagnetic Characterization of Ceramic Composite Tiles for Strategic Applications,” Proceeding of 2016 11th International Conference on Industrial and Information Systems (ICIIS), 2016, pp. 300-303.
8. Wang, H., and Zhu, D., “Design of Radar Absorbing Structure Using SiC f /Epoxy Composites for X Band Frequency Range,” Industrial & Engineering Chemistry Research, Vol. 57, No. 6, 2018, pp. 2139-2145.
9. Li, M., Yin, X., Zheng, G., Chen, M., Tao, M., Cheng, L., and Zhang, L., “High-temperature Dielectric and Microwave Absorption Properties of Si₃N₄-SiC/SiO₂ Composite Ceramics,” Journal of Materials Science, Vol. 50, No. 3, 2015, pp. 1478-1487.
10. Song, H.-H., Zhou, W.-C., Luo, F., Luo, F., Qing, Y.-C., and Chen, M.-L., “Microwave Dielectric Properties of Nextel-440 Fiber Fabrics with Pyrolytic Carbon Coatings in the Temperature Range from Room Temperature to 700°C,” Chinese Physics B, Vol. 24, No. 8, 2015, pp. 088107-1-4.
11. Liu, H., Tian, H., and Cheng, H., “Dielectric Properties of SiC Fiber-reinforced SiC Matrix Composites in the Temperature Range from 25 to 700°C at Frequencies between 8.2 and 18GHz,” Journal of Nuclear Materials, Vol. 432, No. 1-3, 2013, pp. 57-60.
12. Cao, M.-S., Song, W.-L., Hou, Z.-L., Wen, B., and Yuan, J., “The Effects of Temperature and Frequency on the Dielectric Properties, Electromagnetic Interference Shielding and Microwave-absorption of Short Carbon Fiber/silica Composites,” Carbon, Vol. 48, No. 3, 2010, pp. 788-796.
13. Hou, Y., Xiao, B., Sun, Z., Yang, W., Wu, S., Qi, S., Wen, G., and Huang, X., “High Temperature Anti-oxidative and Tunable Wave Absorbing SiC/Fe₃Si/CNTs Composite Ceramic Derived from a Novel Polysilyacetylene,” Ceramics International, Vol. 45, 2019, pp. 16369-16379.
14. Yang, R., Liu, Y., Yu, J., and Wang, K., “Thermal Oxidation Products and Kinetics of Polyethylene Composites,” Polymer Degradation and Stability, Vol. 91, 2006, pp. 1651-1657.
15. Vinoy, K.J., and Jha, R.M., Radar Absorbing Materials: From Theory to Design and Characterization, Kulwer Academic Publishers, USA, 1996.
16. Balanis, C.A., Advanced Engineering Electromagnetics, New York: Wiley, 1989.
17. Haupt, R.L., and Werner, D.H., Genetic Algorithms in Electromagnetics, New Jersey: John Wiley & Sons, 2007.
18. Vinoy, K.J., Jha, R.M., editors. Radar Absorbing Materials, Boston, MA: Springer US, 1996.
19. Shi, X.L., Cao, M.S., Fang, X.Y., Yuan, J., Kang, Y.Q., and Song, W.L., “High Temperature Dielectric Properties and Enhanced Temperature-response Attenuation of β-MnO₂ Nanorods,” Applied Physics Letters, Vol. 93, 2008, pp. 223112.
20. Zhou, W., Yin, R.M., Long, L., Luo, H., Hu, W.D., Ding, Y.H., and Li, Y., “Enhanced High-temperature Dielectric Properties and Microwave Absorption of SiC Nanofibers Modified Si₃N₄ Ceramics Within the Gigahertz Range,” Ceramics International, Vol. 44, 2018, pp. 12301-12307.
21. Song, H.H., Zhou, W.C., Luo, F., Qing, Y.C., and Chen, M.L., “Microwave Dielectric Properties of Nextel-440 Fiber Fabrics with Pyrolytic Carbon Coatings in the Temperature Range from Room Temperature to 700^oC ,” Chinese Physics B, Vol. 24, 2015, pp. 088107.
22. Wen, B., Cao, M.S., Hou, Z.L., Song, W.L., Zhang, L., Lu, M.M., Jin, H.B., Fang, X.Y., Wang, W.Z., and Yuan, J., “Temperature Dependent Microwave Attenuation Behavior for Carbon-nanotube/silica Composites,” Carbon, Vol. 65, 2013, pp. 124-139.
23. Correia, N.T., and Ramos, J.J.M., “On the Cooperativity of the β-relaxation: A Discussion Based on Dielectric Relaxation and Thermally Stimulated Depolarization Currents Data,” Physical Chemistry Chemical Physics, Vol. 2, No. 24, 2000, pp. 5712-5715.
24. Naslain, R.R., “The Design of the Fiber-matrix Interfacial Zone in Ceramic Matrix Composites,” Composites Part A: Applied Science and Manufacturing, Vol. 29, 1998, pp. 1145-1155.
25. Liao, X., Ye, W., Chen, L., Jiang, S., Wang, G., Zhang, L., and Hou, H., “Flexible hdC-G Reinforced Polyimide Composites with High Dielectric Permittivity,” Composites Part A: Applied Science and Manufacturing, Vol. 101, 2017, pp. 50-58.
26. Gama, A.M., Rezende, M.C., and Dantas, C.C., “Dependence of Microwave Absorption Properties on Ferrite Volume Fraction in MnZn Ferrite/rubber Radar Absorbing Materials,” Journal of Magnetism and Magnetic Materials, Vol. 323, 2011, pp. 2782-2785.
27. Cao, M.S., Qin, R., Qiu, C., and Zhu, J., “Matching Design and Mismatching Analysis Towards Radar Absorbing Coatings Based on Conducting Plate,” Materials & Design, Vol. 24, No. 5, 2003, pp. 391-396.
28. Nam, Y.W., Choi, J.H., Lee, W.J., and Kim, C.G., “Thin and Lightweight Radar-absorbing Structure Containing Glass Fabric Coated with Silver By Sputtering,” Composite Structures, Vol. 160, 2017, pp. 1171-1177.
29. Son, D.S., Hyun, J.M., Chaki, S., Park, C.H., and Lee, J.R., “Evaluation of Mechanical/electromagnetic Preformation of Single-sided Active Frequency Selective Surface for Stealth Radomes,” International Journal of Aeronautical and Space Sciences, Vol. 22, 2021, pp. 1235-1242.
30. Tian, H., Liu, H.T., and Cheng, H.F., “A High-temperature Radar Absorbing Structure: Design, Fabrication, and Characterization,” Composites Science and Technology, Vol. 90, 2014, pp. 202-208.
31. Luo, H., Tan, Y., Li, Y., Xiao, P., Deng, L., Zeng, S., Zhang, G., Zhang, H., Zhou, X., and Peng, S., “Modeling for High-temperature Dielectric Behavior of Multilayer Cf/Si₃N₄ Composites in X-band,” Journal of the European Ceramic Society, Vol. 37, 2017, pp. 1961-1968.
32. Chan, K.K., Wong, S., and Riseborough, E., “RCS Predictions and Measurements of a Full-Size Jet Engine Model,” IEEE Antennas and Propagation Society International Symposium, 2005, pp. 868379.
33. Kim, Y.D., Lim, H., Han, J.H., Song, W.Y., and Myung, N.H., “RCS Reduction of Open-ended Circular Waveguide Cavity with Corrugations Using Mode Matching and Scattering Matrix Analysis,” Progress in Electromagnetic Research, Vol. 146, 2014, pp. 57-69.
34. Balakrishnan, P., John, M.J., Pothen, L., Sreekala, M.S., and Thomas, S., “Nature Fiber and Polymer Matrix Composites and Their Application in Aerospace Engineering,” Advanced Composite Materials for Aerospace Engineering, 2016, pp. 365-383.
35. Kim, M.S., “A Study on the Mechanical Properties of MWNT-added Glass/Epoxy Fabric Composites (Master thesis),” KAIST, 2005.
36. Yuan, X., Cheng, L., Guo, S., and Zhang, L., “High-temperature Microwave Absorbing Properties of Ordered Mesoporous Inter-filled SiC/SiO₂Composites,” Ceramics International, Vol. 43, 2017, pp. 282-288.
37. Yang, H.J., Cao, W.Q., Zhang, D.Q., Su, T.J., Shi, H.L., Wang, W.Z., Yuan, J., and Cao, M.S., “NiO Hierarchical Nanorings on SiC: Enhancing Relaxation to Tune Microwave Absorption at Elevated Temperature,” ACS Applied Materials & Interfaces, Vol. 7, 2015, pp. 7073-7077.
38. Chen, I.Q., Yin, X.W., Fan, X.M., Chen, M., Ma, X.K., Cheng, L.F., Zhang, L.T., “Mechanical and Electromagnetic Shielding Properties of Carbon Fiber Reinforced Silicon Carbide Matrix Composites,” Carbon, Vol. 95, 2015, pp. 10-19.
39. Yang, H.J., Cao, M.S., Li, Y., Shi, H.L., Hou, Z.L., Fang, X.Y., Jin, H.B., Wang, W.Z., and Yuan, J., “Enhanced Dielectric Properties and Excellent Microwave Absorption of SiC Powders Driven with NiO Nanorings,” Advanced Optical Materials, Vol. 2, 2014, pp. 214-219.
40. Peng, C.H., Chen, P.S., and Chang, C.C., “High-temperature Microwave Bilayer Absorber Based on Lithium Aluminum Silicate/lithium Aluminum Silicate-SiC Composite,” Ceramics International, Vol. 40, 2014, pp. 47-55.
41. Wang, J., Zhou, W., Luo, F., Zhu, D., and Qing, Y., “Dielectric and Microwave Absorbing Properties of Quartz Fiber/Amorphous Carbon/Polyimide Composites at Elevated Temperature,” Journal of Nanoscience and Nanotechnology, Vol. 17, 2017, pp. 3751-3758.
42. Li, M., Yin, X., Zheng, G., Chen, M., Tao, M., Cheng, L., and Zhang, L., “High-temperature Dielectric and Microwave Absorption Properties of Si₃N₄-SiC/SiO₂ Composite Ceramics,” Journal of Materials Science, Vol. 50, 2015, pp. 1478-1487.
43. Liu, H., Tian, H., and Cheng, H., “Dielectric Properties of SiC Fiber-reinforced SiC Matrix Composites in the Temperature Range from 25 to 700^oC at Frequencies between 8.2 and 18 GHz,” Journal of Nuclear Materials, Vol. 432, 2013, pp. 57-60.
44. Han, T., Luo, R., Cui, G., and Wang, L., “Effect of SiC Nanowires on the High-temperature Microwave Absorption Properties of SiC_f/SiC Composites,” Journal of the European Ceramic Society, Vol. 39, 2019, pp. 1743-1756.
45. Zhou, W., Yin, R.M., Long, L., Luo, H., Hu, W.D., Ding, Y.H., and Li, Y., “Enhanced High-temperature Dielectric Properties and Microwave Absorption of SiC Nanofibers Modified Si3N4 Ceramics Within the Gigahertz Range,” Ceramics International, Vol. 44, 2018, pp. 12301-12307.
46. Dou, Y.K., Li, J.B., Fang, X.Y., Jin, H.B., and Cao, M.S., “The Enhanced Polarization Relaxation and Excellent High-temperature Dielectric Properties of N-doped SiC,” Applied Physics Letters, Vol. 104, 2014, pp. 052102.
47. Song, W.L., Cao, M.S., Hou, Z.L., Yuan, J., and Fang, X.Y., “High-temperature Microwave Absorption and Evolutionary Behavior of Multiwalled Carbon Nanotube Nanocomposite,” Scripta Materialia, Vol. 61, 2009, pp. 201-204.
48. Yuan, X., Cheng, L., and Zhang, L., “Influence Of Temperature on Dielectric Properties and Microwave Absorbing Performances of TiC Nanowires/SiO₂ Composites,” Ceramics International, Vol. 40, 2014, pp. 15391-15397.
49. Wang, H., Zhu, D., Zhou, W., and Luo, F., “Electromagnetic and Microwave Absorbing Properties of Polyimide Nanocomposites at Elevated Temperature,” Journal of Alloys and Compounds, Vol. 648, 2015, pp. 313-319.
50. Ko, H.S., Noh, J.Y., and Lim, H.M., “Effects of Chemical Composition of Ca(OH)₂ and Precursors on the Properties of Fast-Curing Geopolymers,” Korea Journal of Materials Research, Vol. 29, No. 11, 2019, pp. 690-696.

This Article

2022; 35(3): 201-215

Published on Jun 30, 2022
10.7234/composres.2022.35.3.201
Received on May 12, 2022
Revised on Jun 24, 2022
Accepted on Jun 28, 2022

This Article

Services

Shared

Correspondence to