Dual-controllable Plasmon-induced Transparency Based on Active Borophene Metasurface in the Near-infrared Region

Boiler KJ, Imamoglu A, Harris SE (1991) Observation of electromagnetically induced transparency. Phys Rev Lett 66(20):2593–2596

Hau LV, Harris SE, Dutton Z, Behroozi CH (1999) Light speed reduction to 17 metres per second in an ultracold atomic gas. Nature 397(6720):594–598

Kash MM, Sautenkov VA, Zibrov AS, Hollberg L, Welch GR, Lukin MD, Rostovtsev Y, Fry ES, Scully MO (1999) Ultraslow group velocity and enhanced nonlinear optical effects in a coherently driven hot atomic gas. Phys Rev Lett 82(26):5229–5232

Fleischhauer M, Imamoglu A, Marangos JP (2005) Electromagnetically induced transparency: optics in coherent media. Rev Mod Phys 77(2):633–673

Liu CE, Dutton Z, Behroozi CH, Hau LV (2001) Observation of coherent optical information storage in an atomic medium using halted light pulses. Nature 409(6819):490–493

Liu YC, Li BB, Xiao YF (2017) Electromagnetically induced transparency in optical microcavities. Nanophotonics-Berlin 6(5):789–811

Alzar C, Martinez M, Nussenzveig P (2002) Classical analog of electromagnetically induced transparency. Am J Phys 70(1):37–41

Chen Y, Zhu K, Li Y, Fang Y, Wu Q, Sun Y, Chen H (2017) Nonlinear properties of photonic crystal cavity with embedded electromagnetic-induced-transparency-like meta-atoms. Opt Mater Express 7(8):3034

Zhang S, Genov DA, Wang YU, Liu M, Zhang X (2008) Plasmon-induced transparency in metamaterials. Phys Rev Lett 101(4):047401

Liu N, Langguth L, Weiss T, Kästel J, Fleischhauer M, Pfau T, Giessen H (2009) Plasmonic analogue of electromagnetically induced transparency at the Drude damping limit. Nat Mater 8(9):758–762

Liu N, Weiss T, Mesch M, Langguth L, Eigenthaler U, Hirscher M, Sönnichsen C, Giessen H (2010) Planar metamaterial analogue of electromagnetically induced transparency for plasmonic sensing. Nano Lett 10(4):1103–1107

Fan YC, Qiao T, Zhang FL, Fu QH, Dong JJ, Kong BT, Li HQ (2017) An electromagnetic modulator based on electrically controllable metamaterial analogue to electromagnetically induced transparency. Sci Rep 7(1):40441

Ren K, Zhang Y, Ren XB, He YM, Han Q (2021) Polarization-sensitive and active controllable electromagnetically induced transparency in U-shaped terahertz metamaterials. Front Optoelectron 14(2):221–228

Jin XR, Park J, Zheng HY, Lee S, Lee Y, Rhee JY, Kim KW, Cheong HS, Jang WH (2011) Highly-dispersive transparency at optical frequencies in planar metamaterials based on two-bright-mode coupling. Opt Express 19(22):21652–21657

Manjappa M, Turaga SP, Srivastava YK, Bettiol AA, Singh R (2017) Magnetic annihilation of the dark mode in a strongly coupled bright-dark terahertz metamaterial. Opt Lett 42(11):2106–2109

Wang ZF, Fu JH, Zeng QS, Song MX, Denidni TA (2019) High-transmittance absorptive structure based on effect of electromagnetically induced transparency. Ieee Antenn Wirel Pr 18(12):2463–2467

Wan ML, Zhai WQ, Song YL, Li Y, Ji PF, Zhou FQ (2015) Actively controllable EIT-like resonance between localized and propagating surface plasmons for optical switching. J Mod Optic 62(15):1264–1269

Zhang L, Dong ZG, Wang YM, Liu YJ, Zhang S, Kwang J, Yang W, Qiu CW (2018) Polarization-controlled dynamically switchable plasmon-induced transparency in plasmonic metamaterial. Nanoscale 1(41):19517–19523

Xu Q, Su XQ, Ouyang CM, Xu NN, Cao W, Zhang YP, Li Q, Hu C, Gu JQ, Tian Z (2016) Frequency-agile electromagnetically induced transparency analogue in terahertz metamaterials. Opt Lett 41(19):4562–4565

Yahiaoui R, Manjappa M, Srivastava YK, Singh R (2017) Active control and switching of broadband electromagnetically induced transparency in symmetric metadevices. Appl Phys Lett 111(2):021101

Mao LB, Li Y, Li GX, Zhang S, Cao T (2020) Reversible switching of electromagnetically induced transparency in phase change metasurfaces. Adv Photonics 2(5):056004–056004

Li C, Zhu W, Liu Z, Pan RH, Hu S, Du S, Li JJ, Gu CZ (2020) Independent tuning of bright and dark meta-atoms with phase change materials on EIT metasurfaces. Nanoscale 12(18):165–171

Wang DC, Sun S, Feng Z (2020) Enabling switchable and multifunctional terahertz metasurfaces with phase-change material. Opt Mater Express 10(9):2054

Xiao SY, Wang T, Liu TT, Yan XC, Li Z, Xu C (2018) Active modulation of electromagnetically induced transparency analogue in terahertz hybrid metal-graphene metamaterials. Carbon 126:271–278

Shu C, Chen QG, Mei JS, Yin JH (2019) Analogue of tunable electromagnetically induced transparency in terahertz metal-graphene metamaterial. Mater Res Express 6(5):55808

Jia ZP, Huang L, Su JB, Tang B (2021) Tunable electromagnetically induced transparency-like in graphene metasurfaces and its application as a refractive index sensor. J Lightwave Technol 39(5):1544–1549

Xiao BG, Tong SJ, Fyffe A, Shi ZM (2020) Tunable electromagnetically induced transparency based on graphene metamaterials. Opt Express 28(3):4048

Jia ZP, Huang L, Su JB, Tang B (2020) Tunable plasmon-induced transparency based on monolayer black phosphorus by bright-dark mode coupling. Appl Phys Express 13(7):72006

Lian C, Hu SQ, Zhang J, Cheng C, Yuan Z, Gao SW, Meng S (2020) Integrated plasmonics: broadband Dirac plasmons in borophene. Phys Rev Lett 125(11):116802

Dereshgi SA, Liu ZZ, Aydin K (2020) Anisotropic localized surface plasmons in borophene. Opt Express 28(11):16725

Ruan QY, Wang LQ, Bets KV, Yakobson BI (2021) Step-edge epitaxy for borophene growth on insulators. ACS Nano 15(11):18347–18353

Feng BJ, Zhang J, Zhong Q, Li WB, Li S, Li H, Cheng P, Meng S, Chen L, Wu KH (2016) Experimental realization of two-dimensional boron sheets. Nat Chem 8(6):563–568

Zhang CH, Zhang ZZ, Yan WJ, Qin XM (2021) Effect of doping on the photoelectric properties of borophene. Adv Cond Matter Phys 2021:1–7

Zhang JJ, Zhang ZJ, Song XX, Zhang HT, Yang JB (2021) Infrared plasmonic sensing with anisotropic two-dimensional material borophene. Nanomaterials-Basel 11(5):1165

Nong JP, Feng F, Gan JA, Min CJ, Yuan XC, Somekh M (2022) Active modulation of graphene near-infrared electroabsorption employing borophene plasmons in a wide waveband. Adv Opt Mater 10(6):2102131

Nong J, Wei W, Wang W, Lan G, Shang Z, Yi J, Tang L (2018) Strong coherent coupling between graphene surface plasmons and anisotropic black phosphorus localized surface plasmons. Opt Express 26(2):1633

Sensale-Rodriguez B, Yan RS, Kelly MM, Fang T, Tahy K, Hwang WS, Jena D, Liu L, Xing HG (2012) Broadband graphene terahertz modulators enabled by intraband transitions. Nat Commun 3(1):780

Kafaie Shirmanesh G, Sokhoyan R, Pala RA, Atwater HA (2018) Dual-gated active metasurface at 1550 nm with wide (>300°) phase tunability. Nano Lett 18(5):2957–2963

Sabri R, Forouzmand A, Mosallaei H (2020) Multi-wavelength voltage-coded metasurface based on indium tin oxide: independently and dynamically controllable near-infrared multi-channels. Opt Express 28(3):3464

Sabri R, Mosallaei H (2022) Inverse design of perimeter-controlled InAs-assisted metasurface for two-dimensional dynamic beam steering. Nanophotonics 11(20):4515–4530