Vol. 53
Latest Volume
All Volumes
PIERM 128 [2024] PIERM 127 [2024] PIERM 126 [2024] PIERM 125 [2024] PIERM 124 [2024] PIERM 123 [2024] PIERM 122 [2023] PIERM 121 [2023] PIERM 120 [2023] PIERM 119 [2023] PIERM 118 [2023] PIERM 117 [2023] PIERM 116 [2023] PIERM 115 [2023] PIERM 114 [2022] PIERM 113 [2022] PIERM 112 [2022] PIERM 111 [2022] PIERM 110 [2022] PIERM 109 [2022] PIERM 108 [2022] PIERM 107 [2022] PIERM 106 [2021] PIERM 105 [2021] PIERM 104 [2021] PIERM 103 [2021] PIERM 102 [2021] PIERM 101 [2021] PIERM 100 [2021] PIERM 99 [2021] PIERM 98 [2020] PIERM 97 [2020] PIERM 96 [2020] PIERM 95 [2020] PIERM 94 [2020] PIERM 93 [2020] PIERM 92 [2020] PIERM 91 [2020] PIERM 90 [2020] PIERM 89 [2020] PIERM 88 [2020] PIERM 87 [2019] PIERM 86 [2019] PIERM 85 [2019] PIERM 84 [2019] PIERM 83 [2019] PIERM 82 [2019] PIERM 81 [2019] PIERM 80 [2019] PIERM 79 [2019] PIERM 78 [2019] PIERM 77 [2019] PIERM 76 [2018] PIERM 75 [2018] PIERM 74 [2018] PIERM 73 [2018] PIERM 72 [2018] PIERM 71 [2018] PIERM 70 [2018] PIERM 69 [2018] PIERM 68 [2018] PIERM 67 [2018] PIERM 66 [2018] PIERM 65 [2018] PIERM 64 [2018] PIERM 63 [2018] PIERM 62 [2017] PIERM 61 [2017] PIERM 60 [2017] PIERM 59 [2017] PIERM 58 [2017] PIERM 57 [2017] PIERM 56 [2017] PIERM 55 [2017] PIERM 54 [2017] PIERM 53 [2017] PIERM 52 [2016] PIERM 51 [2016] PIERM 50 [2016] PIERM 49 [2016] PIERM 48 [2016] PIERM 47 [2016] PIERM 46 [2016] PIERM 45 [2016] PIERM 44 [2015] PIERM 43 [2015] PIERM 42 [2015] PIERM 41 [2015] PIERM 40 [2014] PIERM 39 [2014] PIERM 38 [2014] PIERM 37 [2014] PIERM 36 [2014] PIERM 35 [2014] PIERM 34 [2014] PIERM 33 [2013] PIERM 32 [2013] PIERM 31 [2013] PIERM 30 [2013] PIERM 29 [2013] PIERM 28 [2013] PIERM 27 [2012] PIERM 26 [2012] PIERM 25 [2012] PIERM 24 [2012] PIERM 23 [2012] PIERM 22 [2012] PIERM 21 [2011] PIERM 20 [2011] PIERM 19 [2011] PIERM 18 [2011] PIERM 17 [2011] PIERM 16 [2011] PIERM 14 [2010] PIERM 13 [2010] PIERM 12 [2010] PIERM 11 [2010] PIERM 10 [2009] PIERM 9 [2009] PIERM 8 [2009] PIERM 7 [2009] PIERM 6 [2009] PIERM 5 [2008] PIERM 4 [2008] PIERM 3 [2008] PIERM 2 [2008] PIERM 1 [2008]
2017-01-02
Design of Carbon Nanotube-Based Broadband Radar Absorber for Ka-Band Frequency Range
By
Progress In Electromagnetics Research M, Vol. 53, 9-16, 2017
Abstract
The general principles of design and development of microwave absorbing materials are discussed and analysed in respect to 26-37 GHz frequency range (Ka-band). Dispersive composite materials based on carbon nanotubes in epoxy resin matrix are produced, and their electromagnetic responses are investigated in Ka-band. Both theoretical and experimental results demonstrate that presented composites may be used as compact e ective absorbers in 26-37 GHz range.
Citation
Dzmitry Bychanok, Gleb Gorokhov, Darya Meisak, Polina Kuzhir, Sergey A. Maksimenko, Yongliang Wang, Zhidong Han, Xin Gao, and Hongyan Yue, "Design of Carbon Nanotube-Based Broadband Radar Absorber for Ka-Band Frequency Range," Progress In Electromagnetics Research M, Vol. 53, 9-16, 2017.
doi:10.2528/PIERM16090303
References

1. Gaylor, K., "Radar absorbing materials-mechanisms and materials," Materials Research Labs Ascot Vale (Australia), No. MRL-TR-89-1, 1989.

2. Qiang, C., J. Xu, Z. Zhang, L. Tian, S. Xiao, Y. Liu, and P. Xu, "Magnetic properties and microwave absorption properties of carbon fibers coated by Fe3O4 nanoparticles," Journal of Alloys and Compounds, Vol. 506, 93-97, 2010.
doi:10.1016/j.jallcom.2010.06.193

3. Tsay, C. Y., R. B. Yang, D. S. Hung, Y. H. Hung, Y. D. Yao, and C. K. Lin, "Investigation on electromagnetic and microwave absorbing properties of La0.7Sr0.3MnO3-d/carbon nanotube composites," Journal of Applied Physics, Vol. 107, 09A502, 2010.
doi:10.1063/1.3337681

4. Danlee, Y., I. Huynen, and C. Bailly, "Thin smart multilayer microwave absorber based on hybrid structure of polymer and carbon nanotubes," Applied Physics Letters, Vol. 100, 213105, 2012.
doi:10.1063/1.4717993

5. Duan, M. C., L. M. Yu, L. M. Sheng, K. An, W. Ren, and X. L. Zhao, "Electromagnetic and microwave absorbing properties of SmCo coated single-wall carbon nanotubes/NiZn-ferrite nanocrystalline composite," Journal of Applied Physics, Vol. 115, 174101, 2014.
doi:10.1063/1.4873636

6. Bychanok, D., A. Plyushch, G. Gorokhov, U. Bychanok, P. Kuzhir, and S. Maksimenko, "Radar absorber based on corrugated composites with carbon fibers," Technical Physics, Vol. 86, 124-128, 2016.

7. Bychanok, D., G. Gorokhov, D. Meisak, A. Plyushch, P. Kuzhir, A. Sokal, K. Lapko, A. Sanchez-Sanchez, V. Fierro, A. Celzard, C. Gallagher, A. P. Hibbins, F. Y. Ogrin, and C. Brosseau, "Exploring carbon nanotubes/BaTiO3/Fe3O4 nanocomposites as microwave absorbers," Progress In Electromagnetics Research C, Vol. 66, 77-85, 2016.
doi:10.2528/PIERC16051106

8. Kim, S.-T. and S.-S. Kim, "Microwave absorbing properties of hollow microspheres plated with magnetic metal films," Journal of Applied Physics, Vol. 115, 17A528, 2014.
doi:10.1063/1.4868916

9. El-Hakim, H. A., K. R. Mahmoud, and A. Abdelaziz, "Design of compact double-layer microwave absorber for X-Ku bands using genetic algorithm," Progress In Electromagnetics Research B, Vol. 65, 157-168, 2016.
doi:10.2528/PIERB15111702

10. Qin, F. and C. Brosseau, "A review and analysis of microwave absorption in polymer composites filled with carbonaceous particles," Journal of Applied Physics, Vol. 111, 061301-24, 2012.
doi:10.1063/1.3688435

11. Bychanok, D., P. Kuzhir, S. Maksimenko, S. Bellucci, and C. Brosseau, "Characterizing epoxy composites filled with carbonaceous nanoparticles from dc to microwave," Journal of Applied Physics, Vol. 113, 124103-6, 2013.
doi:10.1063/1.4798296

12. Brosseau, C., P. Molinie, F. Boulic, and F. Carmona, "Mesostructure, electron paramagnetic resonance, and magnetic properties of polymer carbon black composites," Journal of Applied Physics, Vol. 89, 8297-8310, 2001.
doi:10.1063/1.1371938

13. Kuzhir, P., A. Paddubskaya, D. Bychanok, A. Nemilentsau, M. Shuba, A. Plusch, S. Maksimenko, S. Bellucci, L. Coderoni, F. Micciulla, I. Sacco, G. Rinaldi, J. Macutkevic, D. Seliuta, G. Valusis, and J. Banys, "Microwave probing of nanocarbon based epoxy resin composite films: Toward electromagnetic shielding," Thin Solid Films, Carbon- or Nitrogen-Containing Nanostructured Composite Films, Vol. 519, 4114-4118, 2011.

14. Kanygin, M. A., O. V. Sedelnikova, I. P. Asanov, L. G. Bulusheva, A. V. Okotrub, P. P. Kuzhir, A. O. Plyushch, S. A. Maksimenko, K. N. Lapko, A. A. Sokol, O. A. Ivashkevich, and P. Lambin, "Effect of nitrogen doping on the electromagnetic properties of carbon nanotube-based composites," Journal of Applied Physics, Vol. 113, 144315, 2013.
doi:10.1063/1.4800897

15. Baker-Jarvis, J., M. Janezic, J. J. Grosvenor, and R. Geyer, "Transmission/reflection and short-circuit line methods for measuring permittivity and permeability," NIST Technical Note, 1355, 1993.

16. Zhuravlev, V., V. Suslyaev, E. Korovin, and K. Dorozhkin, "Electromagnetic waves absorbing characteristics of composite material containing carbonyl iron particles," Materials Sciences and Applications, Vol. 5, 803-811, 2014.
doi:10.4236/msa.2014.511080

17. Bychanok, D., S. Li, A. Sanchez-Sanchez, G. Gorokhov, P. Kuzhir, F. Ogrin, A. Pasc, T. Ballweg, K. Mandel, A. Szczurek, V. Fierro, and A. Celzard, "Hollow carbon spheres in microwaves: Bio-inspired absorbing coating," Applied Physics Letters, Vol. 108, 013701, 2016.
doi:10.1063/1.4938537

18. Sarto, M. S., A. G. D'Aloia, A. Tamburrano, and G. De Bellis, "Synthesis, modeling, and experimental characterization of graphite nanoplatelet-based composites for EMC applications," IEEE Transactions on Electromagnetic Compatibility, Vol. 54, 17-27, 2012.
doi:10.1109/TEMC.2011.2178853

19. Cao, M.-S., W.-L. Song, Z.-L. Hou, B.Wen, and J. Yuan, "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, 788-796, 2010.
doi:10.1016/j.carbon.2009.10.028

20. http://nano.bsu.by/products/mwcnt.

21. Okotrub, A. V., L. G. Bulusheva, A. G. Kudashov, V. V. Belavin, and S. V. Komogortsev, "Arrays of carbon nanotubes aligned perpendicular to the substrate surface: Anisotropy of structure and properties," Nanotechnologies in Russia, Vol. 3, 191200, 2008.

22. Bellucci, S., L. Coderoni, F. Micciulla, G. Rinaldi, and I. Sacco, "The electrical properties of epoxy resin composites filled with CNTs and carbon black," Journal of Nanoscience and Nanotechnology, Vol. 11, 9110-9117, 2011.
doi:10.1166/jnn.2011.4281

23., Standard test method for measuring relative complex permittivity and relative magnetic permeability of solid materials at microwave frequencies, ASTM D5568-08, 2009.

24. Bychanok, D., A. Plyushch, K. Piasotski, A. Paddubskaya, S. Voronovich, P. Kuzhir, S. Baturkin, A. Klochkov, E. Korovin, M. Letellier, S. Schaefer, A. Szczurek, V. Fierro, and A. Celzard, "Electromagnetic properties of polyurethane template-based carbon foams in Ka-band," Physica Scripta, Vol. 90, 094019, 2015.
doi:10.1088/0031-8949/90/9/094019