[1] Yao J Q, Chi N, Yang P F et al. Study and outlook of terahertz communication technology[J]. Chinese Journal of Lasers, 36, 2213-2233(2009).
[2] Zhang Z Y. Design and research of reconfigurable array antenna[D](2022).
[3] Shoghi Badr N, Moradi G. Design and analysis of graphene-based THz absorber using multi-layer structure based on increasing profile for conductivity of the graphene layers[J]. Optik, 198, 163239(2019).
[4] Alwareth H, Ibrahim I M, Zakaria Z et al. A wideband high-gain microstrip array antenna integrated with frequency-selective surface for sub-6 GHz 5G applications[J]. Micromachines, 13, 1215(2022).
[5] Malhat H A, Elhenawy A S, Zainud-Deen S H et al. Planar reconfigurable plasma leaky-wave antenna with electronic beam-scanning for MIMO applications[J]. Wireless Personal Communications: An Internaional Journal(2023).
[6] Benlakehal M E, Hocini A, Khedrouche D et al. Design and analysis of MIMO system for THz communication using terahertz patch antenna array based on photonic crystals with graphene[J]. Optical and Quantum Electronics, 54, 693(2022).
[7] Yuan Y, Xie Y N, Li X. Frequency-tunable graphene patch antenna in terahertz regime[J]. Acta Optica Sinica, 38, 0216001(2018).
[8] Li J N, Li C S, Cheng Z Y et al. Multi mode reconfigurable terahertz microstrip antenna based on graphene[J]. Laser & Optoelectronics Progress, 59, 0316006(2022).
[9] Zhang Y Y. Design and research of millimeter wave radar microstrip array antenna[D](2022).
[10] Chu H B, Zhu S C, Duan C H et al. A directional pattern reconfigurable metasurface array antenna working in X-band[C], 265-267(2022).
[11] Fuscaldo W, de Simone S, Dimitrov D et al. Terahertz characterization of graphene conductivity via time-domain reflection spectroscopy on metal-backed dielectric substrates[J]. Journal of Physics D: Applied Physics, 55, 365101(2022).
[12] Tu C, Nagata K, Yan S K. Dependence of electrical conductivity on phase morphology for graphene selectively located at the interface of polypropylene/polyethylene composites[J]. Nanomaterials, 12, 509(2022).
[13] Kolesnikov D V. Numerical investigation of the electrical conductivity of irradiated graphene[J]. Solid State Communications, 308, 113834(2020).
[14] Lü X L. Design of reconfigurable antenna based on graphene[D](2021).
[15] Ram P, Masoodhu B N M, Rachel J Light R. Multilayer screen printed flexible graphene antenna for ISM band applications and energy harvesting[J]. Materials Today: Proceedings, 45, 2508-2513(2021).
[16] Tang W D, Xie Y N, Liu P F. Terahertz band frequency reconfigurable Yagi antenna based on graphene material[J]. Industrial Control Computer, 33, 144-146(2020).
[17] Wang J. Research on miniaturized and reconfigurable antenna based on graphene[D](2019).
[18] Chen X Y, Shi N Y. Comparison and analysis of two conductivity models of graphene[J]. Journal of Shenyang Normal University (Natural Science Edition), 40, 24-29(2022).
[19] Varshney G. Reconfigurable graphene antenna for THz applications: a mode conversion approach[J]. Nanotechnology, 31, 135208(2020).
[20] Zhang J N, Tao S J, Yan X et al. Dual-frequency polarized reconfigurable terahertz antenna based on graphene metasurface and TOPAS[J]. Micromachines, 12, 1088(2021).
[21] Mu Z H, Chen C X, Ma J N et al. An artificial magnetic conductor loaded, polarization reconfigurable circular patch array antenna[J]. International Journal of RF and Microwave Computer-Aided Engineering, 31, e22834(2021).
[22] Mu Y J. Research on antenna and its array of reconfigurable base station with pattern[D](2021).
[23] Niu L S, Lu Q, Hua L et al. Dual-frequency reconfigurable reflect array antenna based on PIN diodes[J]. Research & Progress of SSE, 42, 114-118(2022).