[1] Barnes W L, Dereux A, Ebbesen T W. Surface plasmon subwavelength optics[J]. Nature, 424, 824-830(2003).

[2] Xia S X, Zhai X, Wang L L et al. Excitation of surface plasmons in graphene-coated nanowire arrays[J]. Journal of Applied Physics, 120, 103104(2016).

[3] Xia S X, Zhai X, Huang Y et al. Graphene surface plasmons with dielectric metasurfaces[J]. Journal of Lightwave Technology, 35, 4553-4558(2017).

[4] Fei Z, Rodin A S, Andreev G O et al. Gate-tuning of graphene plasmons revealed by infrared nano-imaging[J]. Nature, 487, 82-85(2012).

[5] Liu Z Q, Liu G Q, Zhou H Q et al. Near-unity transparency of a continuous metal film via cooperative effects of double plasmonic arrays[J]. Nanotechnology, 24, 155203(2013).

[6] He X Y, Gao P Q, Shi W Z. A further comparison of graphene and thin metal layers for plasmonics[J]. Nanoscale, 8, 10388-10397(2016).

[7] Cao G T, Li H J, Deng Y et al. Plasmon-induced transparency in a single multimode stub resonator[J]. Optics Express, 22, 25215-25223(2014).

[8] Vakil A, Engheta N. Transformation optics using graphene[J]. Science, 332, 1291-1294(2011).

[9] Yao G. Research on dynamic modulation characteristics of terahertz metamaterals based on graphene plasmon induced transparency[D](2017).

[10] Fofang N T, Grady N K, Fan Z Y et al. Plexciton dynamics: exciton-plasmon coupling in a J-aggregate-Au nanoshell complex provides a mechanism for nonlinearity[J]. Nano Letters, 11, 1556-1560(2011).

[11] Totsuka K, Kobayashi N, Tomita M. Slow light in coupled-resonator-induced transparency[J]. Physical Review Letters, 98, 213904(2007).

[12] Xia S X, Zhai X, Wang L L et al. Plasmonically induced transparency in double-layered graphene nanoribbons[J]. Photonics Research, 6, 692(2018).

[13] Zhang X, Liu Z M, Zhang Z B et al. Polarization-sensitive triple plasmon-induced transparency with synchronous and asynchronous switching based on monolayer graphene metamaterials[J]. Optics Express, 28, 36771-36783(2020).

[14] Zhang X, Liu Z M, Zhang Z B et al. Photoelectric switch and triple-mode frequency modulator based on dual-PIT in the multilayer patterned graphene metamaterial[J]. Journal of the Optical Society of America A, Optics, Image Science, and Vision, 37, 1002-1007(2020).

[15] Xie Y Y, Chai J X, Ye Y C et al. A tunable slow light device with multiple channels based on plasmon-induced transparency[J]. Plasmonics, 16, 1809-1816(2021).

[16] Xiong C X, Xu H, Zhao M Z et al. Triple plasmon-induced transparency and outstanding slow-light in quasi-continuous monolayer graphene structure[J]. Science China Physics, Mechanics & Astronomy, 64, 224211(2021).

[17] Gao E D, Liu Z M, Li H J et al. Dynamically tunable dual plasmon-induced transparency and absorption based on a single-layer patterned graphene metamaterial[J]. Optics Express, 27, 13884-13894(2019).

[18] Ruan B X, Xiong C X, Liu C et al. Tunable plasmon-induced transparency and slow light in a metamaterial with graphene[J]. Results in Physics, 19, 103382(2020).

[19] Cui W, Li C J, Ma H Q et al. Excellent sensing based on dual-plasmon induced transparency in graphene metasurface[J]. Physica E: Low-Dimensional Systems and Nanostructures, 134, 114850(2021).

[20] Liu Z M, Gao E D, Zhang X et al. Terahertz electro-optical multi-functional modulator and its coupling mechanisms based on upper-layer double graphene ribbons and lower-layer a graphene strip[J]. New Journal of Physics, 22, 053039(2020).

[21] Liu Z M, Gao E D, Li H J et al. Investigation of plasmon-induced transparency and reflection in patterned graphene metamaterial[J]. Journal of Applied Physics, 126, 123101(2019).

[22] Liu Z M, Zhang X, Zhou F Q et al. Triple plasmon-induced transparency and optical switch desensitized to polarized light based on a mono-layer metamaterial[J]. Optics Express, 29, 13949-13959(2021).

[23] Ge J H, You C L, Feng H et al. Tunable dual plasmon-induced transparency based on a monolayer graphene metamaterial and its terahertz sensing performance[J]. Optics Express, 28, 31781-31795(2020).

[24] Liu Z M, Zhang X, Zhang Z B et al. Simultaneous switching at multiple frequencies and triple plasmon-induced transparency in multilayer patterned graphene-based terahertz metamaterial[J]. New Journal of Physics, 22, 083006(2020).

[25] Zhou F Q, Wang Y Q, Zhang X J et al. Dynamically adjustable plasmon-induced transparency and switching application based on bilayer graphene metamaterials[J]. Journal of Physics D: Applied Physics, 54, 054002(2021).

[26] Wang Z Y, Shao J, Hu Y X et al. Electromagnetically induced transparency based on all-dielectric metamaterial with high Q factor[J]. Acta Optica Sinica, 41, 1116001(2021).

[27] Zhang M, Yan F P, Du X M et al. Design and analysis of electromagnetically induced transparency in THz multiband[J]. Chinese Journal of Lasers, 48, 0314001(2021).

[28] Li H Y, Huang W, Zhang Y T et al. Tunable electromagnetically induced transparency based on indium antimonide terahertz metamaterial[J]. Laser & Optoelectronics Progress, 58, 0530002(2021).

[29] Suk J W, Kitt A, Magnuson C W et al. Transfer of CVD-grown monolayer graphene onto arbitrary substrates[J]. ACS Nano, 5, 6916-6924(2011).

[30] Cheng H, Chen S Q, Yu P et al. Dynamically tunable plasmonically induced transparency in periodically patterned graphene nanostrips[J]. Applied Physics Letters, 103, 203112(2013).

[31] Falkovsky L A. Optical properties of graphene[J]. Journal of Physics: Conference Series, 129, 012004(2008).

[32] Falkovsky L A, Pershoguba S S. Optical far-infrared properties of a graphene monolayer and multilayer[J]. Physical Review B, 76, 153410(2007).

[33] Fan S H, Suh W, Joannopoulos J D. Temporal coupled-mode theory for the Fano resonance in optical resonators[J]. Journal of the Optical Society of America A, Optics, Image Science, and Vision, 20, 569-572(2003).

[34] Zhang X, Zhou F Q, Liu Z M et al. Quadruple plasmon-induced transparency of polarization desensitization caused by the Boltzmann function[J]. Optics Express, 29, 29387-29401(2021).

[35] Ahmadivand A, Sinha R, Gerislioglu B et al. Transition from capacitive coupling to direct charge transfer in asymmetric terahertz plasmonic assemblies[J]. Optics Letters, 41, 5333-5336(2016).