[1] L N LANDY, W K SMITH, F J BOSQUESPADILLA et al. Perfect metamaterial absorber. Physical Review Letters, 100, 207402(2008).
[2] P WU, Z CHEN, D XU et al. A narrow dual-band monolayer unpatterned graphene-based perfect absorber with critical coupling in the near infrared. Micromachines, 11, 58(2020).
[3] Zijian CUI, Yue WANG, Dongying ZHU et al. Perfect absorption conditions and absorption characteristics of terahertz metamaterial absorber. Chinese Journal of Lasers, 46, 0614023(2019).
[4] H XIONG, D LI, H ZHANG. Broadband terahertz absorber based on hybrid Dirac semimetal and water. Optics & Laser Technology, 143, 107274(2021).
[5] B MQDA, D TVHAC, C BXKA et al. Graphene-integrated hybridized metamaterials for wide-angle tunable THz absorbers. Photonics and Nanostructures - Fundamentals and Applications, 45, 100924(2021).
[6] B PARVAEI, H R SAGHAI, M ELDLIO. Analysis and simulation of terahertz graphene-based plasmonic waveguide. Optical and Quantum Electronics, 50, 303(2018).
[7] Hong GAO, Fengping YAN, Siyu TAN et al. Design of ultra-thin broadband terahertz metamaterial absorber based on patterned graphene. Chinese Journal of Lasers, 44, 0703024(2017).
[8] P JAIN, S BANSAL, K PRAKASH et al. Graphene-based tunable multi-band metamaterial polarization-insensitive absorber for terahertz applications. Journal of Materials Science: Materials in Electronics, 31, 11878-11886(2020).
[9] N PAPASIMAKIS, S THONGRATTANASIRI, N I ZHELUDEV et al. The magnetic response of graphene split-ring metamaterials. Light: Science & Applications, 2, 78(2013).
[10] T CHEN, W JIANG, X YIN. Dual-band ultrasensitive terahertz sensor based on tunable graphene metamaterial absorber. Superlattices and Microstructures, 154, 106898(2021).
[11] L A WEN, A YL, B JTA et al. A compact metamaterial broadband THz absorber consists of graphene crosses with different sizes. Superlattices and Microstructures, 159, 107038(2021).
[12] Hui LI, Jiang YU, Zhe CHEN. Polarization-independent and incident-angle-insensitive switchablebroadband absorber/reflector based on single-layer graphene. Chinese Journal of Lasers, 47, 0803001(2020).
[13] S ZHENG, Q ZHAO, L PENG et al. Tunable plasmon induced transparency with high transmittance in a two-layer graphene structure. Results in Physics, 104040(2021).
[14] C TAO, Y FENG, Z XIN et al. Terahertz microfluidic sensor based on metamaterial absorbers with enhanced electromagnetic field interaction. Acta Photonica Sinica, 50, 131-141(2021).
[15] H HU, W LIAO, L HOU et al. Ultra-thin ultra-broadband metamaterial absorber based on impedance surface. AEU - International Journal of Electronics and Communications, 153860(2021).
[16] C YUAN, R YANG, J WANG et al. Tunable enhanced bandwidth all-graphene -dielectric terahertz metamaterial absorber/reflector. Optik, 224, 165517(2020).
[17] N YI, R ZONG, J GONG et al. Dynamically tunable broadband absorber with a single ultra-thin layer of graphene in the terahertz regime. Materials Science in Semiconductor Processing, 136, 106161(2021).
[18] B YOU, R ZHANG, S WANG et al. A high-performance broadband terahertz absorber based on single layer cross-shaped graphene. Optik, 241, 167249(2021).
[19] Z CHEN, H CHEN, H JILE et al. Multi-band multi-tunable perfect plasmon absorber based on L-shaped and double-elliptical graphene stacks. Diamond and Related Materials, 108374(2021).
[20] Y QI, Y ZHANG, C LIU et al. A tunable terahertz metamaterial absorber composed of hourglass-shaped graphene arrays. Nanomaterials (Basel), 10, 533(2020).
[21] Z WANG, X WANG, J WANG et al. Independently tunable dual-broadband terahertz absorber based on two-layer graphene metamaterial. Optik, 247, 167958(2021).
[22] H LI, J NIU, G WANG. Dual-band, polarization-insensitive metamaterial perfect absorber based on monolayer graphene in the mid-infrared range. Results in Physics, 13, 102313(2019).
[23] H AHMADI, S VAEZI, V J HARZAND et al. Graphene-based terahertz metamaterial absorber for broadband applications. Solid State Communications, 323, 114023(2020).
[24] Y CHENG, H ZHAO, C LI. Broadband tunable terahertz metasurface absorber based on complementary-wheel-shaped graphene. Optical Materials, 109, 110369(2020).
[25] C WANG. Highly transparent broadband and polarization-insensitive absorber based on metasurface. Applied Sciences, 10, 9125(2020).
[26] Z XU, D WU, Y LIU et al. Design of a tunable ultra-broadband terahertz absorber based on multiple layers of graphene ribbons. Nanoscale Research Letters, 13, 143(2018).
[27] Y CAI, S LI, Y ZHOU et al. Tunable and anisotropic dual-band metamaterial absorber using elliptical graphene-black phosphorus pairs. Nanoscale Research Letters, 14, 346(2019).
[28] D YAN, M MENG, J LI et al. Graphene-assisted narrow bandwidth dual-band tunable terahertz metamaterial absorber. Frontiers in Physics, 8, 306(2020).