[1] [1] DRISCOLL T, ANDREEV G O, BASOV D N, et al. Tuned perme-ability in terahertz split-ring resonators for devices and sensors[J]. Applied Physics Letters, 2007,91(6):062511.

[2] [2] DENG H C, JIANG X W, HUANG X X, et al. A temperature sensor based on composite optical waveguide［J］. Journal of Lightwave Technology,2022,40(8):2663-2669.

[3] [3] TIAN X Y, LI L W, CHEW S X, et al. Cascaded optical microring resonator based auto-correction assisted high resolution microwave photonic sensor［J］. Journal of Lightwave Technology,2021,39(24):7646-7655.

[4] [4] ZHANG Y Y, ZHANG J H, LI Y N, et al. An optical intense 2D electric field sensor using a single LiNO3 crystal［J］. Current Optics and Photonics,2022, 6(2):183-190.

[5] [5] WOO B H, SEO I C, LEE E, et al. Angle-dependent optical perfect absorption and enhanced photoluminescence in excitonic thin films［J］. Optics Express,2017,25(23):28619-28629.

[6] [6] YILDIRIM D U, GHOBADI A, SOYOAN M C, et al. One-way and near-absolute polarization insensitive near perfect absorption by using an all dielectric metasurface［J］. Optics Letters,2020,45(7):2010-2013.

[7] [7] YU H H. Study on structure and properties of polarization-sensitive metamaterial absorber［D］. Changchun: Jilin University,2021:23-34(in Chinese).

[8] [8] WANG R. Research on fabrication and characterization of subwavelength metallic grating-based polarimetric sensor［D］.Shanghai: Shanghai Institute of Technical Physics Chinese Academy of Sciences,2016:21-28(in Chinese).

[9] [9] WANG P F, HE F Y, LIU J J, et al. High-Q terahertz all-dielectric metasurface based on bound states in the continuum［J］. Laser Technology, 2022, 46(5):630-635(in Chinese).

[10] [10] ALAEE R, FARHAT M, ROCKSTUHL C, et al. A perfect absorber made of a graphene micro-ribbon metamaterial［J］. Optics Express,2012,20(27):28017-28024.

[11] [11] AKHAVAN A, ABDOLHOSSEINI S, GHAFOORIFARD H, et al. Narrow band total absorber at near-infrared wavelengths using monolayer graphene and sub-wavelength grating based on critical coupling［J］. Journal of Lightwave Technology,2018,36(23):5593-5599.

[12] [12] SHAO Y B. Investigation on optical nonlinear absorption and carrier dynamics of several 2D materials［D］.Harbin: Heilongjiang University,2021:11-14(in Chinese).

[13] [13] LI Sh L. Research on the novel tunable terahertz modulator of black phosphorus［D］. Xi’an:Xi’an University of Science and Technology,2021:10-12(in Chinese).

[14] [14] TANG B, YANG N G, HUANG L, et al. Tunable anisotropic perfect enhancement absorption in black phosphorus-based metasurfaces［J］. IEEE Photonics Journal, 2020, 12(3):4500209.

[15] [15] DONG D X, LIU Y W, FEI Y , et al. Designing a nearly perfect infrared absorber in monolayer black phosphorus［J］. Applied Optics, 2019, 58(14):3862-3869.

[16] [16] WANG J, JIANG Y N, HU Zh R. Dual-band and polarization-independent infrared absorber based on two-dimensional black phosphorus metamaterials［J］. Optics Express, 2017, 25(18):22149-22157.

[17] [17] DAI X Y, CHEN H , QIU Ch Y, et al. Ultrasensitive multiple guided-mode biosensor with few-layer black phosphorus［J］. Journal of Lightwave Technology, 2020, 38(6):1564-1571.

[18] [18] CAI Y J, XU K D, FENG N X, et al. Anisotropic infrared plasmo-nic broadband absorber based on graphene-black phosphorus multilayers［J］.Optics Express,2020,27(3):3101-3112.

[19] [19] ZHU Y Q, TANG B, JIANG Ch. Tunable ultra-broadband anisotropic absorbers based on multi-layer black phosphorus ribbons［J］. Applied Physics Express, 2019,12(3), 032009.

[20] [20] KHALILZADEH H,SHARIF A H, ANVARHAGHIGAI N. Design of a broadband infrared absorber based on multiple layers of black phosphorus nanoribbons［J］. Journal of the Optical Society of America,2021,B38(12):3920-3928.

[21] [21] WANG Sh Q, LI Sh L, ZHOU Y G, et al. Enhanced terahertz modulation using a plasmonic perfect absorber based on black phosphorus［J］. Applied Optics, 2020, 59(29):9279-9283.

[22] [22] XIAO Sh Y, LIU T T, CHENG L, et al. Tunable anisotropic absorption in hyperbolic metamaterials based on black phosphorous/dielectric multilayer structures［J］. Journal of Lightwave Technology, 2019,37(13):3290-3297.

[23] [23] HE Zh H, LU H, ZHAO J L. Polarization independent and non-reciprocal absorption in multi-layer anisotropic black phosphorus metamaterials［J］. Optics Express, 2021, 29(14):21336-21347.

[24] [24] WU Sh W, JIAN R D, XIONG G P. High-performance polarization-independent black phosphorus refractive index sensors enabled by a single-layer pattern design［J］. Optics Letters, 2022,47(3):517-520.

[25] [25] FANG Y W. Study on new liquid dye laser［D］. Hefei: University of Science and Technology of China, 2021: 3-10(in Chinese).

[26] [26] LIN C, GRASSI R, LOW T, et al. Multilayer black phosphorus as a versatile mid-infrared electro-optic material［J］. Nano Letters, 2016,16(3):1683-1689.

[27] [27] CAI Y J, LI Sh L, ZHOU Y G, et al. Investigation of multi-resonant and anisotropic plasmonic resonances in the stacked graphene-black phosphorus bilayers［J］. Journal of Physics D: Applied Physics, 2020,53(2):025107.

[28] [28] FAN Sh H, SUH W J, JOANNOPOULOS J D. Temporal coupled-mode theory for the Fano resonance in optical resonators［J］. Journal of the Optical Society of America, 2003, A20(3):569-572.

[29] [29] LIU T T, JIANG X J, ZHOU Ch B, et al. Black phosphorus-based anisotropic absorption structure in the mid-infrared［J］. Optics Express, 2019, 27(20):27618-27627.

[30] [30] PANG H Zh, WANG X, WANG J L, et al. Sensing characteristics of dual band terahertz metamaterial absorber sensor［J］. Acta Physica Sinica,2021,70(16):168101(in Chinese).

[31] [31] ZHANG J J, ZHANG Zh J, SONG X X, et al. Infrared plasmonic sensing with anisotropic two-dimensional material borophene［J］. Nanomaterials, 2021,11(5):1165.

[32] [32] ZHANG J A, LI G M, ZHOU Y G, et al. Research on multi-resonant refractive index sensor based on black phosphorus［J］. Journal of Air Force Engineering University (Natural Science Edition), 2022, 23(1):43-48(in Chinese).

[33] [33] ZHOU R L, PENG J, YANG S, et al. Lifetime and nonlinearity of modulated surface plasmon for black phosphorus sensing application［J］. Nanoscale,2018,10:18878-18891.

[34] [34] CHEN H, XIONG L, HU F R, et al. Ultrasensitive and tunable sensor based on plasmon-induced transparency in a black phosphorus metasurface［J］. Plasmonics, 2021,16(4):1071-1077.

[35] [35] LIU Ch, LI H J, XU H, et al. Plasmonic biosensor based on excellently absorbable adjustable plasmon-induced transparency in black phosphorus and graphene metamaterials［J］. New Journal of Physics, 2020,22:073049.

[36] [36] SHEN H Y, LIU Ch Y, LIU F X. et al. Multi-band plasmonic absorber based on hybrid metal-graphene metasurface for refractive index sensing application［J］. Results in Physics, 2021,23:104020.

[37] [37] JIANG X P, CHEN D B, ZHANG Zh J, et al. Dual-channel optical switch, refractive index sensor and slow light device based on a graphene metasurface［J］. Optics Express, 2020, 28(23):34079-34092.

[38] [38] QIU C Y, WU J H, ZHU R R, et al. Dual-band near-perfect metamaterial absorber based on cylinder MoS2-dielectric arrays for sensors［J］. Optics Communications, 2019,451:226-230.