[1] Rappaport T S, Xing Y, Kanhere O et al. Wireless communications and applications above 100 GHz: opportunities and challenges for 6g and beyond[J]. IEEE Access, 7, 78729-78757(2019).

[2] Elayan H, Amin O, Shihada B et al. Terahertz band: the last piece of RF[J]. IEEE Open Journal of The Communications Society, 1, 1-32(2020).

[3] Xia F, Wang H, Xiao D et al. Two-dimensional material nanophotonics[J]. Nature Photonics, 8, 899(2014).

[4] Bao Q, Zhang H, Wang Y et al. Atomic‐layer graphene as a saturable absorber for ultrafast pulsed lasers[J]. Advanced Functional Material, 19, 3077(2009).

[5] Yao B, Liu Y, Huang S W et al. roadband gate-tunable terahertz plasmons in graphene heterostructures[J]. Nature Photonics, 12, 22(2018).

[6] Yao B, Huang S W, Liu Y et al. Gate-tunable frequency combs in graphene-nitride microresonators[J]. Nature, 558, 410(2018).

[7] Tanh K Z, Su Y, Qin M et al. Dynamically tunable coherent perfect absorption and transparency in Dirac semimetal metasurface[J]. Optical Materials Express, 9, 3649-3656(2019).

[8] Zhang Y, Lv J, Que L, C et al. A double-band tunable perfect terahertz metamaterial absorber based on Dirac semimetals[J]. Results in Physics, 15, 102773-102781(2019).

[9] Meng W W, Que L C, Lv J et al. A triple-band terahertz metamaterial absorber based on buck Dirac Semimetals[J]. Results in Physics, 14, 102461-102467(2019).

[10] Liu G D, Zhai X, Meng H Y et al. Dirac semimetals based tunable narrowband absorber at terahertz frequencies[J]. Optics Express, 26, 11471-11480(2018).

[11] Fang P P, Shi X W, Liu C et al. Single- and dual-band convertible terahertz absorber based on bulk Dirac semimetal[J]. Optics Communication, 462, 125333-12539(2020).

[12] Chen L L, Song Z Y. Simultaneous realizations of absorber and transparent conducting metal in a single metamaterial[J]. Optics Express, 28, 6565-6571(2020).

[13] Zhou L, Liang J Y, Hu M et al. Enhanced luminous transmittance of thermochromic VO2 thin film patterned by SiO2 nanospheres[J]. Applied Physics Letter, 110, 193901-193903(2017).

[14] Zhao J X, Song J L, Zhou Y et al. Multi-functional vanadium dioxide integrated metamaterial for terahertz wave manipulation[J]. Chinese physics B, 29, 094205-094209(2020).

[15] Ran L J, Jun W M, Hu M et al. Fabrication of VO2 thin film by rapid thermal annealing in oxygen atmosphere and its metal—insulator phase transition properties[J]. Chinese physics B, 23, 076801-076804(2020).

[16] Liu Y N, Weng X L, Zhang P et al. Ultra-broadband infrared metamaterial absorber for passive radiative cooling[J]. Chinese Physics Letter, 38, 034201-034204(2021).

[17] Nouman M T, Hwang J H, Faiyaz M et al. Vanadium dioxide based frequency tunable metasurface filters for realizing reconfigurable terahertz optical phase and polarization control[J]. Optics Express, 26, 12922-12929(2018).

[18] Wahlstrand J K, Heilweil E J. Contactless THz-based bulk semiconductor mobility measurements using two-photon excitation[J]. Optics Express, 26, 29848-29853(2018).

[19] Li Z X, Wang T L, Qu L F et al. Design of bi-tunable triple-band metamaterial absorber based on Dirac semimetal and vanadium dioxide[J]. Optical Materials Express, 10, 1941-1950(2020).

[20] Ban S H, Meng H Y, Zhai X et al. Tunable triple-band and broadband convertible metamaterial absorber with bulk Dirac semimetal and vanadium dioxide[J]. Journal of Physics D: Applied Physics, 54, 174001-174004(2021).

[21] Cao M Y, Wang T L, Li L et al. Tunable bifunctional polarizationindependent metamaterial device based on Dirac semimetal and vanadium dioxide[J]. Journal of the Optical Society of America A, 37, 1340-1349(2020).

[22] Kang W J, Gao Q G, Dai L L et al. Dual-controlled tunable terahertz coherent perfect absorption using Dirac semimetal and vanadium dioxide[J]. Results in Physics, 19, 103688-103693(2020).

[23] Wang T L, Zhang H Y, Zhang Y P et al. A bi-tunable switchable polarization-independent dual-band metamaterial terahertz absorber using VO2 and Dirac semimetal[J]. Results in Physics, 19, 103484-103487(2020).

[24] Hu B J, Huang M, Li P et al. Dynamically dual-tunable dual-band to four-band metamaterial absorbers based on bulk Dirac semimetal and vanadium dioxide[J]. Journal of the Optical Society of America A, 39, 383-391(2022).

[25] Liu M, Kang W, Zhang Y et al. Dynamically controlled terahertz coherent absorber engineered with VO2-integrated Dirac semimetal metamaterials[J]. Optics Communication, 503, 127443(2022).

[26] Kotov O V, Lozovik Y E. Dielectric response and novel electromagnetic modes in three-dimensional Dirac semimetal films[J]. Physical Review B, 93, 235417-235421(2016).

[27] Zhou J, Chang H R, Xiao D et al. Plasmon mode as a detection of the chiral anomaly in Weyl semimetals[J]. Physical Review B, 91, 035114-035117(2015).

[28] Lv M, Zhang S. Dielectric function, Friedel oscillation and plasmons in Weyl semimetal[J]. International Journal of Modern Physics B, 27, 1350177-1350179(2013).

[29] Zhao J X, Song J L, Zhou Y et al. Tunable multiple plasmoninduced transparency in a simple terahertz Dirac semimetal based metamaterial[J]. Optical Materials Express, 9, 3325-3332(2019).

[30] Wang Q, Wang X L, Zhang L W et al. Tunable defect modes of one-dimensional photonic crystals containing a Dirac semimetalbased metamaterial defect layer[J]. Applied Optics, 58, 94-101(2019).

[31] Zhang Z J, Yang J B, Han Y X et al. Actively tunable terahertz electromagnetically induced transparency analogue based on vanadium-oxide-assisted metamaterials[J]. Applied Physics A, 126, 1-11(2020).

[32] Zhao X J, Song L J, Zhou Y et al. Multi-functional vanadium dioxide integrated metamaterial for terahertz wave manipulation[J]. Chinese physics B, 29, 094205(2020).

[33] He X, Yao Y, Zhu Z et al. Active graphene metamaterial absorber for terahertz absorption bandwidth, intensity and frequency control[J]. Optical Materials Express, 8, 1031(2018).

[34] Huang H, Xia H, Xie W et al. Design of broadband graphene-metamaterial absorbers for permittivity sensing at mid-infrared regions[J]. Scientific Report, 8, 4183(2018).

[35] Smith D R, Vier D C, Koschny T et al. Electromagnetic parameter retrieval from inhomogeneous metamaterials[J]. Physical Review E, 71, 036617(2005).