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PIER PIER B PIER C PIER M PIER Letters
2017-01-02
Design of Carbon Nanotube-Based Broadband Radar Absorber for Ka-Band Frequency Range
By
Dzmitry Bychanok,

    Dr. Dzmitry Bychanok

    Research Institute for Nuclear Problems Belarusian State University

    Belarus

    Homepage

Gleb Gorokhov,

    Dr. Gleb Gorokhov

    Research Institute for Nuclear Problems Belarusian State University

    Belarus

    Homepage

Darya Meisak,

    Dr. Darya Meisak

    Research Institute for Nuclear Problems Belarusian State University

    Belarus

    Homepage

Polina Kuzhir,

    Dr. Polina Kuzhir

    Bobruiskaya Str 11

    Byelarus

    Homepage

Sergey A. Maksimenko,

    Dr. Sergey A. Maksimenko

    1Research Institute for Nuclear Problems

    Belarusian State University

    Republic of Belarus

    Homepage

Yongliang Wang,

    Dr. Yongliang Wang

    Harbin University of Science and Technology

    China

    Homepage

Zhidong Han,

    Dr. Zhidong Han

    Harbin University of Science and Technology

    China

    Homepage

Xin Gao,

    Dr. Xin Gao

    Harbin University of Science and Technology

    China

    Homepage

Hongyan Yue

    Dr. Hongyan Yue

    Harbin University of Science and Technology

    China

    Homepage

Progress In Electromagnetics Research M, Vol. 53, 9-16, 2017
doi:10.2528/PIERM16090303 | Google Scholar

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.
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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
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