基于锑化铟的可调超材料太赫兹带阻滤波器
[1] Claus R. Electrons catch a terahertz wave [J].Science,2016,352(6284):410-411.
[2] Masanori H. Development and future prospects of terahertz technology[J]. Japanese Journal of Applied Physics,2015,54(12):1-16.
[3] Zhong M, Han G M. Tunable broad stop-band filter based on multilayer metamaterials in the THz regime [J]. J.Infrared Millim.Waves,2016,35(1): 11-15.
[4] Mao Q, Wen Q Y, Tian W, et al. High-speed and broadband terahertz wave modulators based on large-area grapheme field-effect transistors [J].Optics Letters, 2014,39(19):5649-5652.
[5] Liu Y, Zhang Y Q, Jin X R, et al. Dual-band infrared perfect absorber for plasmonic sensor based on the electromagnetically induced reflection-like effect [J].Optics Communications, 2016,371:173-177.
[6] Chen S, Fan F, Wang X H, et al. Terahertz isolator based on nonreciprocal magneto metasurface [J].Optics Express,2015,23(2):1015-1024.
[7] Jia X L, Meng Q X, Yuan C X, et al. A novel chiral nano structure for optical activities and negative refractive index [J]. Optik,2016,127(14):5738-5742.
[8] Schurig D, Mock J J, Justice B J, et al. Metamaterial electromagnetic cloak at microwave frequencies [J].Science,2006,314(5801):977-980.
[9] Patrick R, Cumali S. Wide-band polarization independent perfect metamaterrial absorber based on concentric ring topology for solar cells application [J].Journal of Alloys and Compounds, 2016,680: 473-479.
[10] Li Q, Zhang X Q, Cao W, et al. An approach for mechanically tunable, dynamic terahertz bandstop filters[J].Applied Physics A, 2012,107(2):285-291.
[11] Kadir O, Okan M Y, Hasan K. Metamaterial based broadband RF absorber at X-band [J]. Int.J.Electron. Commun.(AEU), 2016,70(8):1062-1070.
[12] Wang G C, Zhang J N, Zhang B, et al. Photo-excited terahertz switch based on composite metamaterial structure [J].Optics Communications, 2016,374: 64-68.
[13] Hu J R, Li J S, Cheng W. Research on a thermally tunable terahertz wave band-stop filter based on thermo-sensitive media[J].Electronic components and materials(胡建荣,李九生,程伟. 基于温敏介质的温控太赫兹波带阻滤波器研究. 电子元件与材料), 2014,33(5):57-60.
[14] Cheng W. Research on tunable terahertz wave devices using metamaterials and photonic crystals[D]. Hang zhou: China Jiliang University(程伟. 基于电磁超材料和光子晶体的可调太赫兹波器件研究. 杭州: 中国计量大学),2014.
[15] Marcelo A B, Assis A K T. A new method for inductance calculations [J]. J. Phys.D: Appl. Phys, 1995,28(9): 1802-1806.
[16] Gevorgian S, Berg H. Line capacitance and impedance of coplanar-strip waveguides on substrates with multiple dielectric layers [J]. In 31st European Microwave Conference, 2001.
[17] Passmore B S, Allen D G, Vangala S R, et al. Mid-infrared doping tunable transmission through subwavelength metal hole arrays on InSb[J]. Optics Express,2009,17(12):10223-10230.
[18] Zhu J, Han J G, Tian Z, et al. Thermal broadband tunable Terahertz metamaterials [J]. Optics Communications, 2011,284:3129-3133.
[19] Gu W H, Chang S J, Fan F, et al. InSb-based tunable terahertz directional beaming device [J]. Optics Communications, 2016,377:110-114.
白育堃, 魏仁霄, 马秀荣, 马颖. 基于锑化铟的可调超材料太赫兹带阻滤波器[J]. 红外与毫米波学报, 2017, 36(3): 261. BAI Yu-Kun, WEI Ren-Xiao, MA Xiu-Rong, MA Ying. Tunable metamaterial Terahertz band-stop filter based on InSb[J]. Journal of Infrared and Millimeter Waves, 2017, 36(3): 261.