[1] J. X. Li, S. W. Yang, C. H. Wang, W. T. Joines, Q. H. Liu. Metamaterial cavity for the isolation enhancement of closely positioned dual-polarized relay antenna arrays. Microw. Opt. Techn. Lett., 59, 857(2017).
[2] S. K. Patel, K. H. Shah, Y. P. Kosta. Multilayer liquid metamaterial radome design for performance enhancement of microstrip patch antenna. Microw. Opt. Techn. Lett., 60, 600(2018).
[3] C. M. Saleh, D. Bensafieddine, E. M. Laamari, M. Bouzouad. A zero-index metamaterial single layer superstrate for patch antenna gain enhancement. Acta Phys. Pol., 128, B307(2015).
[4] C. P. Scarborough, Z. H. Jiang, D. H. Werner, C. Rivero-Baleine, C. Drake. Experimental demonstration of an isotropic metamaterial super lens with negative unity permeability at 8.5 MHz. Appl. Phys. Lett., 101, 014101(2012).
[5] Y. H. Zhao, A. A. Nawaz, S. C. S. Lin, Q. Z. Hao, B. Kiraly, T. J. Huang. Nanoscale super-resolution imaging via a metal–dielectric metamaterial lens system. J. Phys. D, 44, 415101(2011).
[6] X. J. Huang, H. L. Yang, Z. Y. Shen, J. Chen, H. I. Lin, Z. T. Yu. Water-injected all-dielectric ultra-wideband and prominent oblique incidence metamaterial absorber in microwave regime. J. Phys. D, 50, 385304(2017).
[7] C. L. Xu, B. K. Wang, M. B. Yan, Y. Q. Pang, W. J. Wang, Y. Y. Meng, J. F. Wang, S. B. Qu. An optical-transparent metamaterial for high-efficiency microwave absorption and low infrared emission. J. Phys. D, 53, 135109(2019).
[8] N. Landy, S. Sajuyigbe, J. Mock, D. Smith, W. Padilla. Perfect metamaterial absorber. Phys. Rev. Lett., 100, 207402(2008).
[9] J. Bucinskas, L. Nickelson, V. Shugurovas. Microwave scattering and absorption by a multilayered lossy metamaterial-glass cylinder. Prog. Electromagn. Res., 105, 103(2010).
[10] W. Luo, X. Wang, S. Wang, X. Wang, Z. Liu, L. Li, F. Hu, Y. Wen, J. Zhou. Miniaturization of dielectric ceramic-based metamaterial perfect absorber. Appl. Phys. Lett., 120, 013502(2022).
[11] J. Y. Jung, J. Lee, D. G. Choi, J. H. Choi, J. H. Jeong, E. S. Lee, D. P. Neikirk. Wavelength-selective infrared metasurface absorber for multispectral thermal detection. IEEE Photonics J., 7, 6804210(2015).
[12] S. W. Dai, D. Zhao, Q. Li, M. Qiu. Double-sided polarization-independent plasmonic absorber at near-infrared region. Opt. Express, 21, 13125(2013).
[13] D. Wu, R. F. Li, Y. M. Liu, Z. Y. Yu, L. Yu, L. Chen, C. Liu, R. Ma, H. Ye. Ultra-narrow band perfect absorber and its application as plasmonic sensor in the visible region. Nanoscale Res. Lett., 12, 427(2017).
[14] M. L. Li, B. Muneer, Z. X. Yi, Q. Zhu. A broadband compatible multispectral metamaterial absorber for visible, near-infrared, and microwave bands. Adv. Opt. Mater., 6, 1701238(2018).
[15] B. Grzeskiewicz, A. Sierakowski, J. Marczewski, N. Palka, E. Wolarz. Polarization-insensitive metamaterial absorber of selective response in terahertz frequency range. J. Opt., 16, 105104(2014).
[16] H. Kong, G. F. Li, Z. M. Jin, G. H. Ma, Z. W. Zhang, C. L. Zhang. Polarization-independent metamaterial absorber for terahertz frequency. J. Infrared Millim. Terahertz Waves, 33, 649(2012).
[17] X. Liu, T. Tyler, T. Starr, A. F. Starr, N. M. Jokerst, W. J. Padilla. Taming the blackbody with infrared metamaterials as selective thermal emitters. Phys. Rev. Lett., 107, 045901(2011).
[18] M. L. Hakim, T. Alam, A. F. Almutairi, M. F. Mansor, M. T. Islam. Polarization insensitivity characterization of dual-band perfect metamaterial absorber for K band sensing applications. Sci. Rep., 11, 17829(2021).
[19] J. Luo, H. Chu, R. Peng, M. Wang, J. Li, Y. Lai. Ultra-broadband reflectionless Brewster absorber protected by reciprocity. Light Sci. Appl., 10, 89(2021).
[20] F. Wu, X. H. Wu, S. Y. Xiao, G. H. Liu, H. J. Li. Broadband wide-angle multilayer absorber based on a broadband omnidirectional optical Tamm state. Opt. Express, 29, 23976(2021).
[21] J. Luo, H. Chu, R. Peng, M. Wang, J. Li, Y. Lai. Ultra-broadband reflectionless Brewster absorber protected by reciprocity. Light Sci. Appl., 10, 89(2021).
[22] Y. Zhou, Z. Qin, Z. Liang, D. Meng, H. Xu, D. R. Smith, Y. Liu. Ultra-broadband metamaterial absorbers from long to very long infrared regime. Light Sci. Appl., 10, 138(2021).
[23] C. M. Watts, X. Liu, W. J. Padilla. Metamaterial electromagnetic wave absorbers. Adv. Mater., 24, 98(2012).
[24] D. Yevick, D. J. Thomson. Impedance-matched absorbers for finite-difference parabolic equation algorithms. J. Acoust. Soc. Am., 107, 1226(2000).
[25] N. Luhmann, D. Hoj, M. Piller, H. Kähler, M.-H. Chien, R. G. West, U. L. Andersen, S. Schmid. Ultrathin 2 nm gold as impedance-matched absorber for infrared light. Nat. Commun., 11, 2161(2020).
[26] M. Y. Pan, L. B. Wang, S. L. Dou, J. P. Zhao, H. B. Xu, B. Wang, L. P. Zhang, X. B. Li, L. Pan, Y. Li. Recent advances in colloidal photonic crystal-based anti-counterfeiting materials. Crystals, 9, 417(2019).
[27] C. Jung, Y. Yang, J. Jang, T. Badloe, T. Lee, J. Mun, S. W. Moon, J. J. Rho. Near-zero reflection of all-dielectric structural coloration enabling polarization-sensitive optical encryption with enhanced switchability. Nanophotonics, 10, 919(2021).
[28] G. H. Rui, C. C. Ding, B. Gu, Q. Q. Gan, Q. W. Zhan, Y. P. Cui. Symmetric Ge2Sb2Te5 based metamaterial absorber induced dynamic wide-gamut structural color. J. Opt., 22, 085003(2020).
[29] S. U. Kim, S. H. Lee, I. H. Lee. Generation of intensity-tunable structural color from helical photonic crystals for full color reflective-type display. Sci. Adv., 4, 8829(2018).
[30] S. L. Li, M. C. Panmai, S. L. Tie, Y. Xu, J. Xiang, S. Lan. Regulating disordered plasmonic nanoparticles into polarization sensitive metasurfaces. Nanophotonics, 10, 1553(2021).
[31] H. Z. Zhu, Q. Li, C. N. Tao, Y. Hong, Z. Q. Xu, W. D. Shen, S. Kaur, P. Ghosh, M. Qiu. Multispectral camouflage for infrared, visible, lasers and microwave with radiative cooling. Nat. Commun., 12, 1805(2021).
[32] D. J. Ironside, R. Salas, P. Y. Chen, K. Q. Le, A. Alu, S. R. Bank. Enhancing THz generation in photomixers using a metamaterial approach. Opt. Express, 27, 9481(2019).
[33] R. M. Saadabad, L. Huang, A. E. Miroshnichenko. Polarization-independent perfect absorber enabled by quasibound states in the continuum. Phys. Rev. B, 104, 235405(2021).
[34] J. F. Zhang, Q. L. Hong, J. L. Zou, Q. Meng, S. Q. Qin, Z. H. Zhu. Ultra-narrowband visible light absorption in a monolayer MoS2 based resonant nanostructure. Opt. Express, 28, 27608(2020).
[35] Z. B. Li, X. A. Sun, C. R. Ma, J. Li, X. P. Li, B. O. Guan, K. Chen. Ultra-narrow-band metamaterial perfect absorber based on surface lattice resonance in a WS2 nanodisk array. Opt. Express, 29, 27084(2021).
[36] J. Xiang, M. Panmai, S. W. Bai, Y. H. Ren, G. C. Li, S. L. Li, J. Liu, J. T. Li, M. X. Zeng, J. C. She, Y. Xu, S. Lan. Crystalline silicon white light sources driven by optical resonances. Nano Lett., 21, 2397(2021).
[37] Y. T. Chen, J. Dai, M. Yan, M. Qiu. Metal-insulator-metal plasmonic absorbers: influence of lattice. Opt. Express, 22, 30807(2014).
[38] B. Gerislioglu, L. Dong, A. Ahmadivand, H. Hu, P. Nordlander, N. J. Halas. Monolithic metal dimer-on-film structure: new plasmonic properties introduced by the underlying metal. Nano Lett., 20, 2087(2020).
[39] M. Pan, Z. C. Su, Z. F. Yu, P. H. Wu, H. G. Jile, Z. Yi, Z. Q. Chen. A narrowband perfect absorber with high Q-factor and its application in sensing in the visible region. Results Phys., 19, 103415(2020).
[40] D. Hu, T. H. Meng, H. Y. Wang, Y. K. Ma, Q. F. Zhu. Ultra-narrow-band terahertz perfect metamaterial absorber for refractive index sensing application. Results Phys., 19, 103567(2020).
[41] A. Vazquez-Guardado, M. Money, N. Mckinney, D. Chanda. Multi-spectral infrared spectroscopy for robust plastic identification. Appl. Opt., 54, 7396(2015).
[42] X. L. Wu, Y. Zheng, Y. Luo, J. G. Zhang, Z. Yi, X. W. Wu, S. B. Cheng, W. X. Yang, Y. Yu, P. H. Wu. A four-band and polarization-independent BDS-based tunable absorber with high refractive index sensitivity. Phys. Chem. Chem. Phys., 23, 26864(2021).
[43] W. H. Yang, S. M. Xiao, Q. H. Song, Y. L. Liu, Y. K. Wu, S. Wang, J. Yu, J. C. Han, D. P. Tsai. All-dielectric metasurface for high-performance structural color. Nat. Commun., 11, 1864(2020).
[44] Q. B. Fan, M. Z. Liu, C. Zhang, W. Q. Zhu, Y. L. Wang, P. C. Lin, F. Yan, L. Chen, H. J. Lezec, Y. Q. Lu, A. Agrawal, T. Xu. Independent amplitude control of arbitrary orthogonal states of polarization via dielectric metasurfaces. Phys. Rev. Lett., 125, 267402(2020).
[45] F. Yan, Q. Li, H. Tian, Z. W. Wang, L. Li. An ultrahigh Q-factor dual-band terahertz perfect absorber with a dielectric grating slit waveguide for sensing. J. Phys. D, 53, 235103(2020).
[46] Y. H. Ko, N. Razmjooei, H. Hemmati, R. Magnusson. Perfectly-reflecting guided-mode-resonant photonic lattices possessing Mie modal memory. Opt. Express, 29, 26971(2021).
[47] N. Razmjooei, Y. H. Ko, F. A. Simlan, R. Magnusson. Resonant reflection by microsphere arrays with AR-quenched Mie scattering. Opt. Express, 29, 19183(2021).
[48] G. C. Li, J. Xiang, Y. L. Zhang, F. Deng, M. Panmai, W. J. Zhuang, S. Lan, D. Y. Lei. Mapping the magnetic field intensity of light with the nonlinear optical emission of a silicon nanoparticle. Nano Lett., 21, 2453(2021).
[49] H. Lin, B. C. P. Sturmberg, K.-T. Lin, Y. Yang, X. Zheng, T. K. Chong, C. M. Sterke, B. Jia. A 90-nm-thick graphene metamaterial for strong and extremely broadband absorption of unpolarized light. Nat. Photonics, 13, 270(2019).
[50] S. Lee, J. Song, S. Kim. Graphene perfect absorber with loss adaptive Q-factor control function enabled by quasi-bound states in the continuum. Sci. Rep., 11, 22819(2021).
[51] X. K. He, Z. Y. Sun, Q. T. Zou, L. Y. Wu, J. B. Jiang. Electrochemical behavior of Co (II) reduction for preparing nanocrystalline Co catalyst for hydrogen evolution reaction from 1-ethyl-3-methylimidazolium bisulfate and ethylene glycol system. J. Electrochem. Soc., 166, D57(2019).
[52] M. L. Shi, F. Lan, P. Mazumder, M. Aghadjani, Z. Q. Yang, L. Meng, J. Zhou. Enhanced quadruple-resonant terahertz metamaterial with asymmetric hybrid resonators. Opt. Mater., 75, 533(2018).
[53] H. Li, J. Niu, G. Wang. Dual-band, polarization-insensitive metamaterial perfect absorber based on monolayer graphene in the mid-infrared range. Results Phys., 13, 102313(2019).
[54] Z. Q. Liu, G. Q. Liu, G. L. Fu, X. S. Liu, Y. Wang. Multi-band light perfect absorption by a metal layer-coupled dielectric metamaterial. Opt. Express, 24, 5020(2016).
[55] Y. Y. Wang, Z. Q. Chen, D. Y. Xu, Z. Yi, X. F. Chen, J. Chen, Y. J. Tang, P. H. Wu, G. F. Li, Y. G. Yi. Triple-band perfect metamaterial absorber with good operating angle polarization tolerance based on split ring arrays. Results Phys., 16, 102951(2020).
[56] Q. Li, J. Lu, P. Gupta, M. Qiu. Engineering optical absorption in graphene and other 2D materials: advances and applications. Adv. Opt. Mater., 7, 1900595(2019).
[57] H. J. Li, B. Chen, X. Zhai, L. Xu, L. L. Wang. Tunable ultra-multispectral metamaterial perfect absorbers based on out-of-plane metal-insulator-graphene heterostructures. J. Lightwave Technol., 38, 1858(2019).
[58] L. Zhou, Y. Tan, D. Ji, B. Zhu, P. Zhang, J. Xu, Q. Gan, Z. Yu, J. Zhu. Self-assembly of highly efficient, broadband plasmonic absorbers for solar steam generation. Sci. Adv., 2, e1501227(2016).
[59] L. Zhou, Y. Tan, J. Zhu. Broadband plasmonic absorbers for highly efficient solar steam generation. Optical Nanostructures and Advanced Materials for Photovoltaics, PW3B.3(2015).
[60] P. D. Dongare, A. Alabastri, O. Neumann, P. Nordlander, N. J. Halas. Solar thermal desalination as a nonlinear optical process. Proc. Natl. Acad. Sci. U.S.A., 116, 13182(2019).
[61] K. T. Lin, H. Lin, T. S. Yang, B. H. Jia. Structured graphene metamaterial selective absorbers for high efficiency and omnidirectional solar thermal energy conversion. Nat. Commun., 11, 1389(2020).
[62] Y. Liu, F. Wang, X. Wang, X. Wang, E. Flahaut, X. Liu, Y. Li, X. Wang, Y. Xu, Y. Shi. Planar carbon nanotube-graphene hybrid films for high-performance broadband photodetectors. Nat. Commun., 6, 8589(2015).
[63] Y. Liu, Q. Hu, Y. Wang, Y. Xie, Z. Zhao, Z. Dong, J.-L. Zhu, W. Chu, N. Yang, J. Wei, W. Ma, J.-L. Sun. High-performance, ultra-broadband, ultraviolet to terahertz photodetectors based on suspended carbon nanotube films. ACS Appl. Mater. Interfaces, 10, 36304(2018).
[64] Y. L. Liao, Y. Zhao. Ultra-narrowband dielectric metamaterial absorber with ultra-sparse nanowire grids for sensing applications. Sci. Rep., 10, 3966(2020).
[65] H. J. Zhang, Z. Q. Liu, H. Z. Zhong, G. Q. Liu, X. S. Liu, J. Q. Wang. Metal-free plasmonic refractory core-shell nanowires for tunable all-dielectric broadband perfect absorbers. Opt. Express, 28, 37049(2020).
[66] S. Ijaz, A. Rana, Z. Ahmad, B. Rehman, M. Zubair, M. Mehmood. Exploiting zirconium nitride for an efficient heat-resistant absorber and emitter pair for solar thermophotovoltaic systems. Opt. Express, 29, 31537(2021).
[67] Y. Li, Z. Liu, P. Pan, X. Liu, G. Fu, Z. Liu, H. Luo, G. Liu. Semiconductor-nanoantenna-assisted solar absorber for ultra-broadband light trapping. Nanoscale Res. Lett., 15, 816(2020).
[68] K. L. Zhang, J. Y. Zhang, Z. L. Hou, S. Bi, Q. L. Zhao. Multifunctional broadband microwave absorption of flexible graphene composites. Carbon, 141, 608(2019).
[69] J. Liu, W. Ma, W. Chen, G. Yu, Y. Chen, X. Deng, C. Yang. Numerical analysis of an ultra-wideband metamaterial absorber with high absorptivity from visible light to near-infrared. Opt. Express, 28, 23748(2020).
[70] Y. Jin, K. Yu. Broadband single-channel coherent perfect absorption with a perfect magnetic mirror. Opt. Express, 28, 35108(2020).
[71] L. Zhao, H. Liu, Z. H. He, S. K. Dong. All-metal frequency-selective absorber/emitter for laser stealth and infrared stealth. Appl. Opt., 57, 1757(2018).
[72] Y. J. Cai, K. D. Xu, N. Feng, R. Guo, H. Lin, J. Zhu. Anisotropic infrared plasmonic broadband absorber based on graphene-black phosphorus multilayers. Opt. Express, 27, 3101(2019).
[73] H. Ullah, A. D. Khan, M. Noman, A. U. Rehman. Novel multi-broadband plasmonic absorber based on a metal-dielectric-metal square ring array. Plasmonics, 13, 591(2017).
[74] X. Ruan, W. Dai, W. Wang, C. Ou, Q. Xu, Z. Zhou, Z. Wen, C. Liu, J. Hao, Z. Guan, H. Xu. Ultrathin, broadband, omnidirectional, and polarization-independent infrared absorber using all-dielectric refractory materials. Nanophotonics, 10, 1683(2021).
[75] Y. Zhou, Z. Qin, Z. Liang, D. Meng, H. Xu, D. R. Smith, Y. Liu. Ultra-broadband metamaterial absorbers from long to very long infrared regime. Light Sci. Appl., 10, 138(2021).
[76] Z. Qin, X. Shi, F. Yang, E. Hou, D. Meng, C. Sun, R. Dai, S. Zhang, H. Liu, H. Xu, Z. Liang. Multi-mode plasmonic resonance broadband LWIR metamaterial absorber based on lossy metal ring. Opt. Express, 30, 473(2022).
[77] S. Yue, M. Hou, R. Wang, H. Guo, Y. Hou, M. Li, Z. Zhang, Y. Wang, Z. Zhang. Ultra-broadband metamaterial absorber from ultraviolet to long-wave infrared based on CMOS-compatible materials. Opt. Express, 28, 31844(2020).
[78] T. Liu, J. Takahara. Ultrabroadband absorber based on single-sized embedded metal-dielectric-metal structures and application of radiative cooling. Opt. Express, 25, A612(2017).
[79] A. Hoque, M. T. Islam, A. F. Almutairi, M. Faruque. Design of split hexagonal patch array shaped nano-metaabsorber with ultra-wideband absorption for visible and UV spectrum application. Nanoscale Res. Lett., 14, 393(2019).
[80] Q. Cheng, P. Li, J. Lu, X. Yu, H. L. Zhou. Silicon complex grating with different groove depths as an absorber for solar cells. J. Quant. Spectrosc. Radiat. Transfer, 132, 70(2014).
[81] P. Bouchon, C. Koechlin, F. Pardo, R. Haïdar, J. L. Pelouard. Wideband omnidirectional infrared absorber with a patchwork of plasmonic nanoantennas. Opt. Lett., 37, 1038(2012).
[82] N. Nguyen-Huu, J. Pistora, M. Cada. Dual broadband infrared absorptance enhanced by magnetic polaritons using graphene-covered compound metal grating. Opt. Express, 27, 30182(2019).
[83] J. L. Song, M. T. Si, Q. Cheng, Z. X. Luo. Two-dimensional trilayer grating with a metal/insulator/metal structure as a thermophotovoltaic emitter. Appl. Opt., 55, 1284(2016).
[84] A. P. Raman, M. A. Anoma, L. Zhu, E. Rephaeli, S. Fan. Passive radiative cooling below ambient air temperature under direct sunlight. Nature, 515, 540(2014).
[85] S. Kamau, S. Hassan, K. Alnasser, H. L. Zhang, J. B. Cui, Y. K. Lin. Broadband absorption in patterned metal/weakly-absorbing-spacer/metal with graded photonic super-crystal. Photonics, 8, 114(2021).
[86] E. Rephaeli, A. Raman, S. Fan. Ultrabroadband photonic structures to achieve high-performance daytime radiative cooling. Nano Lett., 13, 1457(2013).
[87] A. Saib, L. Bednarz, R. Daussin, C. Bailly, X. Lou, J.-M. Thomassin, C. Pagnoulle, C. Detrembleur, R. Jerome, I. Huynen. Carbon nanotube composites for broadband microwave absorbing materials. IEEE Trans. Microwave Theory Tech., 54, 2745(2006).
[88] D. Katzen, E. Levy, Y. Mastai. Thin films of silica–carbon nanocomposites for selective solar absorbers. Appl. Surf. Sci., 248, 514(2005).
[89] M. K. Hedayati, M. Javaherirahim, B. Mozooni, R. Abdelaziz, A. Tavassolizadeh, V. S. K. Chakravadhanula, V. Zaporojtchenko, T. Strunkus, F. Faupel, M. Elbahri. Design of a perfect black absorber at visible frequencies using plasmonic metamaterials. Adv. Mater., 23, 5410(2011).
[90] X. F. Chen, Y. Zhou, H. W. Han, X. Y. Wang, L. Zhou, Z. Yi, Z. J. Fu, X. W. Wu, G. F. Li, L. C. Zeng. Optical and magnetic properties of small-size core–shell Fe3O4@C nanoparticles. Mater. Today Chem., 22, 100556(2021).
[91] L. Zhou, Y. Zhou, Y. F. Zhu, X. X. Dong, B. L. Gao, Y. Z. Wang, S. Shen. Broadband bidirectional visible light absorber with wide angular tolerance. J. Mater. Chem. C, 4, 391(2016).
[92] H. Lin, B. C. Sturmberg, K.-T. Lin, Y. Yang, X. Zheng, T. K. Chong, C. M. de Sterke, B. Jia. A 90-nm-thick graphene metamaterial for strong and extremely broadband absorption of unpolarized light. Nat. Photonics, 13, 270(2019).
[93] S. Thongrattanasiri, F. H. Koppens, F. J. G. De Abajo. Complete optical absorption in periodically patterned graphene. Phys. Rev. Lett., 108, 047401(2012).
[94] F. Q. Zhou, F. Qin, Z. Yi, W. T. Yao, Z. M. Liu, X. W. Wu, P. H. Wu. Ultra-wideband and wide-angle perfect solar energy absorber based on Ti nanorings surface plasmon resonance. Phys. Chem. Chem. Phys., 23, 17041(2021).
[95] T. Cao, K. Liu, L. Lu, H. C. Chui, R. E. Simpson. Large-area broadband near-perfect absorption from a thin chalcogenide film coupled to gold nanoparticles. ACS Appl. Mater. Interfaces, 11, 5176(2019).
[96] F. Kiani, F. Sterl, T. V. Tsoulos, K. Weber, H. Giessen, G. Tagliabue. Ultra-broadband and omnidirectional perfect absorber based on copper nanowire/carbon nanotube hierarchical structure. ACS Photonics, 7, 366(2020).
[97] F. Garcia-Vidal, J. Pitarke, J. Pendry. Effective medium theory of the optical properties of aligned carbon nanotubes. Phys. Rev. Lett., 78, 4289(1997).
[98] L. Zhou, Y. Tan, J. Wang, W. Xu, Y. Yuan, W. Cai, S. Zhu, J. Zhu. 3D self-assembly of aluminium nanoparticles for plasmon-enhanced solar desalination. Nat. Photonics, 10, 393(2016).
[99] W. Ali, M. F. Mideksa, K. Hou, H. D. Li, X. L. Wang, Z. Y. Tang. All-solution-processed ultrahigh broadband and wide-angle perfect absorber based on mxene-gold nanoparticles. Adv. Opt. Mater., 8, 2000447(2020).
[100] C. C. Chang, S. C. Kuo, H. E. Cheng, H. T. Chen, Z. P. Yang. Broadband titanium nitride disordered metasurface absorbers. Opt. Express, 29, 42813(2021).
[101] Y. J. Jen, K. B. Yang, P. C. Lin, M. H. Chung. Deposited ultra-thin titanium nitride nanorod array as a plasmonic near-perfect light absorber. Sci. Rep., 10, 22269(2020).
[102] W. Li, U. Guler, N. Kinsey, G. V. Naik, A. Boltasseva, J. Guan, V. M. Shalaev, A. V. Kildishev. Refractory plasmonics with titanium nitride: broadband metamaterial absorber. Adv. Mater., 26, 7959(2014).
[103] D. H. Jiang, J. Qu, X. Xu, K. Liu, W. J. Sun. Light absorption characteristics of AAO/Ag NPs composite system. Acta Photonica Sin., 48, 131001(2019).
[104] P. Bouchut, F. Geffraye, J. Bablet, F. Emieux. Ultrabroadband plasmonic induced transparency in random metamaterial with nanocavity. Opt. Mater., 98, 109439(2019).
[105] N. Sharma, J. Bar-David, N. Mazurski, U. Levy. Metasurfaces for enhancing light absorption in thermoelectric photodetectors. ACS Photonics, 7, 2468(2020).
[106] H. Cai, Y. Sun, X. Wang, S. Zhan. Design of an ultra-broadband near-perfect bilayer grating metamaterial absorber based on genetic algorithm. Opt. Express, 28, 15347(2020).
[107] Y. Kim, P. Park, J. Jo, J. Lee, L. Jeong, J. Shin, J.-H. Lee, H. J. Lee. Ultrawideband electromagnetic metamaterial absorber utilizing coherent absorptions and surface plasmon polaritons based on double layer carbon metapatterns. Sci. Rep., 11, 23045(2021).
[108] L. Chen, T. X. Ren, Y. Zhao, Q. Yu, Z. L. Huang, K. Zhang, J. Wen, F. Lin, S. Q. Chen. Polarization-independent wavefront manipulation of surface plasmons with plasmonic metasurfaces. Adv. Opt. Mater., 8, 2000868(2020).
[109] Y. Cui, K. Fung, J. Xu, H. Ma, Y. Jin, S. He, N. Fang. Ultrabroadband light absorption by a sawtooth anisotropic metamaterial slab. Nano Lett., 12, 1443(2012).
[110] S. He, F. Ding, L. Mo, F. Bao. Light absorber with an ultra-broad flat band based on multi-sized slow-wave hyperbolic metamaterial thin-films. Prog. Electromagn. Res., 147, 69(2014).
[111] H. Deng, C. J. Mathai, S. Gangopadhyay, J. Gao, X. Yang. Ultra-broadband infrared absorption by tapered hyperbolic multilayer waveguides. Opt. Express, 26, 6360(2018).
[112] S. Hu, S. Yang, Z. Liu, B. Quan, J. Li, C. Gu. Broadband and polarization-insensitive absorption based on a set of multisized Fabry-Perot-like resonators. J. Phys. Chem. C, 123, 13856(2019).
[113] Q. Liang, T. Wang, Z. Lu, Q. Sun, Y. Fu, W. Yu. Metamaterial-based two dimensional plasmonic subwavelength structures offer the broadest waveband light harvesting. Adv. Opt. Mater., 1, 43(2013).
[114] T. Chen, M. Yub, Y. Lu, T. Yen. Ultra-broadband, lithography-free, omnidirectional, and polarization-insensitive perfect absorber. Sci. Rep., 11, 5173(2021).
[115] J. Zhao, Y. Wang, Y. Zhu, W. Zhang, Y. Yu. Lithography-free, flexible perfect broadband absorber in visible light based on all-dielectric multilayer structure. Opt. Lett., 45, 5464(2020).
[116] C. Dong, K.-S. Shen, Y. Zheng, H.-C. Liu, J. Zhang, S.-Q. Xia, F. Wu, H. Lu, X.-Z. Zhang, Y.-F. Liu. Quasiperiodic metamaterials empowered non-metallic broadband optical absorbers. Opt. Express, 29, 13576(2021).
[117] H. Zhong, H. Zhang, Z. Liu, X. Liu, G. Liu. Super-absorbers by randomly distributed titanium spheres. IEEE Photon. Technol. Lett., 33, 247(2021).
[118] Z. Guo, X. Liu, C. Li, J. Li, H. Cai, M. Fu, D. He, Y. Wang. Near-perfect broadband metamaterial absorbers of truncated nanocones using colloidal lithography. Opt. Mater., 119, 111352(2021).
[119] J. Zhou, X. Liu, H. Zhang, M. Liu, Q. Yi, Z. Liu, J. Wang. Cross-shaped titanium resonators based metasurface for ultra-broadband solar absorption. IEEE Photon. J., 13, 3052990(2021).
[120] Q. Qian, C. Wang, L. Fan, L. Cheng, H. Chen, L. Zhao. An ultra-broadband metasurface perfect absorber based on the triple Mie resonances. Opt. Mater., 116, 111103(2021).
[121] R. Piao, D. Zhang. Ultra-broadband perfect absorber based on nanoarray of titanium nitride truncated pyramids for solar energy harvesting. Physica E Low Dimens. Syst. Nanostruct., 134, 114829(2021).
[122] H. Zhang, M. Luo, Y. Zhou, Y. Ji, L. Chen. Ultra-broadband, polarization-independent, wide-angle near-perfect absorber based on one-dimensional meta-surface from UV to near-infrared region. Opt. Mater. Express, 10, 484(2020).
[123] H. Zhang, L. Feng, Y. Liang, T. Xu. An ultra-flexible plasmonic metamaterial film for efficient omnidirectional and broadband optical absorption. Nanoscale, 11, 437(2019).
[124] J. Grant, Y. Ma, S. Saha, A. Khalid, D. R. Cumming. Polarization insensitive, broadband terahertz metamaterial absorber. Opt. Lett., 36, 3476(2011).
[125] D. M. Nguyen, D. Lee, J. Rho. Control of light absorbance using plasmonic grating based perfect absorber at visible and near-infrared wavelengths. Sci. Rep., 7, 2611(2017).
[126] K. Chen, R. Adato, H. Altug. Dual-band perfect absorber for multispectral plasmon-enhanced infrared spectroscopy. ACS Nano, 6, 7998(2012).
[127] M. Pu, C. Hu, M. Wang, C. Huang, Z. Zhao, C. Wang, Q. Fang, X. Luo. Design principles for infrared wide-angle perfect absorber based on plasmonic structure. Opt. Express, 19, 17413(2011).
[128] C. Han, R. Zhong, Z. Liang, L. Yang, Z. Fang, Y. Wang, A. Ma, Z. Wu, M. Hu, D. Liu, S. Liu. Independently tunable multipurpose absorber with single layer of metal-graphene metamaterials. Materials, 14, 284(2021).
[129] Y. Zhao, Q. Huang, H. Cai, X. Lin, H. He, T. Ma, Y. Lu. Dual band and tunable perfect absorber based on dual gratings-coupled graphene-dielectric multilayer structures. Opt. Express, 27, 5217(2019).
[130] Y. Zhang, T. Li, Q. Chen, H. Zhang, J. F. O’Hara, E. Abele, A. J. Taylor, H. Chen, A. K. Azad. Independently tunable dual-band perfect absorber based on graphene at mid-infrared frequencies. Sci. Rep., 5, 18463(2015).
[131] X. Han, Y. B. Wu, J. Dong, M. C. Tang, Y. N. Jiang, X. P. Zeng. Ultra-thin and broadband tunable metamaterial graphene absorber. Opt. Express, 26, 1681(2018).
[132] M. Wuttig, H. Bhaskaran, T. Taubner. Phase-change materials for non-volatile photonic applications. Nat. Photonics, 11, 465(2017).
[133] Q. Y. Wen, H. W. Zhang, Q. H. Yang, Y. S. Xie, K. Chen, Y. L. Liu. Terahertz metamaterials with VO2 cut-wires for thermal tunability. Appl. Phys. Lett., 97, 021111(2010).
[134] Y. Chen, X. Li, X. Luo, S. Maier, M. Hong. Tunable near-infrared plasmonic perfect absorber based on phase-change materials. Photon. Res., 3, 54(2015).
[135] J. Jeong, A. Joushaghani, S. Paradis, D. Alain, J. K. S. Poon. Electrically controllable extraordinary optical transmission in gold gratings on vanadium dioxide. Opt. Lett., 40, 4408(2015).
[136] L. Wang, E. Radue, S. Kittiwatanakul, C. Clavero, J. Lu, S. A. Wolf, I. Novikova, R. A. Lukaszew. Surface plasmon polaritons in VO2 thin films for tunable low-loss plasmonic applications. Opt. Lett., 37, 4335(2012).
[137] C. Peng, K. Ou, G. Li, X. Li, W. Wang, Z. Zhao, X. Li, X. Chen, W. Lu. Tunable phase change polaritonic perfect absorber in the mid-infrared region. Opt. Express, 28, 11721(2020).
[138] Z. Zheng, Y. Zheng, Y. Luo, Z. Yi, J. Zhang, Z. Liu, W. Yang, Y. Yu, X. Wu, P. Wu. A switchable terahertz device combining ultra-wideband absorption and ultra-wideband complete reflection. Phys. Chem. Chem. Phys., 24, 2527(2022).
[139] Y. Yao, R. Shankar, M. A. Kats, Y. Song, J. Kong, M. Loncar, F. Capasso. Electrically tunable metasurface perfect absorbers for ultrathin mid-infrared optical modulators. Nano Lett., 14, 6526(2014).
[140] Y. Yang, K. Kelley, E. Sachet, S. Campione, T. S. Luk, J.-P. Maria, M. B. Sinclair, I. Brener. Femtosecond optical polarization switching using a cadmium oxide-based perfect absorber. Nat. Photonics, 11, 390(2017).
[141] J. He, M. Zhang, S. Shu, Y. Yan, M. Wang. VO2 based dynamic tunable absorber and its application in switchable control and real-time color display in the visible region. Opt. Express, 28, 37590(2020).
[142] D. N. Ma, H. Cheng, J. G. Tian, S. Q. Chen. Inverse design methods and applications of photonics devices (Invited). Acta Photonica Sin., 51, 0151110(2022).
[143] H. Yu, Y. Peng, Y. Yang, Z. Y. Li. Plasmon-enhanced light–matter interactions and applications. NPJ Computat. Mater., 5, 45(2019).
[144] D. G. Baranov, A. Krasnok, T. Shegai, A. Alu, Y. D. Chong. Coherent perfect absorbers: linear control of light with light. Nat. Rev. Mater, 2, 17064(2017).
[145] S. A. Mann, E. C. Garnett. Resonant nanophotonic spectrum splitting for ultrathin multijunction solar cells. ACS Photonics, 2, 816(2015).
[146] F. Dincer, O. Akgol, M. Karaaslan, E. Unal, C. Sabah. Polarization angle independent perfect metamaterial absorbers for solar cell applications in the microwave, infrared, and visible regime. Prog. Electromagn. Res., 144, 93(2014).
[147] S. M. Kim, J. S. Won, S. H. Nahm. Simultaneous reception of solar power and visible light communication using a solar cell. Opt. Eng., 53, 046103(2014).
[148] P. Rufangura, C. Sabah. Wide-band polarization independent perfect metamaterial absorber based on concentric rings topology for solar cells application. J. Alloys Compd., 680, 473(2016).
[149] C. F. Huang, W. Y. Hsieh, B. C. Hsieh, C. H. Hsieh, C. F. Lin. Characterization of InGaN-based photovoltaic devices by varying the indium contents. Thin Solid Films, 529, 278(2013).
[150] G. E. Cirlin, A. D. Bouravleuv, I. P. Soshnikov, Y. B. Samsonenko, V. G. Dubrovskii, E. M. Arakcheeva, E. M. Tanklevskaya, P. Werner. Photovoltaic properties of p-doped GaAs nanowire arrays grown on n-type GaAs(111)B substrate. Nano. Res. Lett., 5, 360(2009).
[151] X. Tang, M. M. Ackerman, P. Guyot-Sionnest. Thermal imaging with plasmon resonance enhanced HgTe colloidal quantum dot photovoltaic devices. ACS Nano, 12, 7362(2018).
[152] I. A. Hummelgen. Organic electronic solid state device: electrochemistry of material preparation. J. Solid State Electrochem., 21, 1977(2017).
[153] S. Mallawaarachchi, M. Premaratne, S. D. Gunapala, P. K. Maini. Tuneable superradiant thermal emitter assembly. Phys. Rev. B, 95, 155443(2017).
[154] G. Liu, X. Liu, J. Chen, Y. Li, L. Shi, G. Fu, Z. Liu. Near-unity, full-spectrum, nanoscale solar absorbers and near-perfect blackbody emitters. Sol. Energ. Mater. Sol. C, 190, 20(2019).
[155] X. Liu, T. Tyler, T. Starr, A. F. Starr, N. M. Jokerst, W. J. Padilla. Taming the blackbody with infrared metamaterials as selective thermal emitters. Phys. Rev. Lett., 107, 045901(2011).
[156] Y. Nam, Y. Yeng, A. Lenert, P. Bermel, I. Celanovic, M. Soljačić, E. N. Wang. Solar thermophotovoltaic energy conversion systems with two-dimensional tantalum photonic crystal absorbers and emitters. Sol. Energ. Mater. Sol. C, 122, 287(2014).
[157] Y. Li, X. Bai, D. Yuan, F. Zhang, B. Li, X. San, B. Liang, S. Wang, J. Luo, G. Fu. General heterostructure strategy of photothermal materials for scalable solar-heating hydrogen production without the consumption of artificial energy. Nat. Commun., 13, 776(2022).
[158] Z. H. Liu, H. Y. Guan, G. S. Wang. Performance optimization study on an integrated solar desalination system with multi-stage evaporation/heat recovery processes. Energy, 76, 1001(2014).
[159] Z. H. Liu, R. L. Hu, X. J. Chen. A novel integrated solar desalination system with multi-stage evaporation/heat recovery processes. Renew. Energy, 64, 26(2014).
[160] S. F. Li, Z. H. Liu, Z. X. Shao, H. S. Xiao, N. Xia. Performance study on a passive solar seawater desalination system using multi-effect heat recovery. Appl. Energy, 213, 343(2018).
[161] L. Zhou, S. D. Zhuang, C. Y. He, Y. L. Tan, Z. L. Wang, J. Zhu. Self-assembled spectrum selective plasmonic absorbers with tunable bandwidth for solar energy conversion. Nano Energy, 32, 195(2017).
[162] L. Li, Y. Liu, P. Hao, Z. Wang, L. Fu, Z. Ma, J. Zhou. PEDOT nanocomposites mediated dual-modal photodynamic and photothermal targeted sterilization in both NIR I and II window. Biomaterials, 41, 132(2015).
[163] S. Pirnat, M. Lukac, A. Ihan. Study of the direct bactericidal effect of Nd:YAG and diode laser parameters used in endodontics on pigmented and nonpigmented bacteria. Lasers Med. Sci., 26, 755(2011).
[164] W. H. Wang, H. B. Wang, P. Yu, K. Sun, X. Tong, F. Lin, C. Wu, Y. M. You, W. Z. Xie, Y. P. Li, C. Z. Yuan, A. O. Govorov, O. L. Muskens, H. X. Xu, S. Sun, Z. M. Wang. Broadband thin-film and metamaterial absorbers using refractory vanadium nitride and their thermal stability. Opt. Express, 29, 33456(2021).
[165] K. Aydin, V. E. Ferry, R. M. Briggs, H. A. Atwater. Broadband polarization-independent resonant light absorption using ultrathin plasmonic super absorbers. Nat. Commun., 2, 517(2011).
[166] Z. Li, S. Butun, K. Aydin. Lithography-free transmission filters at ultraviolet frequencies using ultra-thin aluminum films. J. Opt., 18, 065006(2016).
[167] R. Yang, C. Dai, C. Wan, G. Zheng, Z. Li. Planar ultrathin omni-directional perfect absorber utilizing amorphous silicon for photovoltaics. Opt. Mater. Express, 10, 532(2020).
[168] B. Wang, E. Stevens, P. W. Leu. Strong broadband absorption in GaAs nanocone and nanowire arrays for solar cells. Opt. Express, 22, A386(2014).
[169] I. Massiot, N. Vandamme, N. Bardou, C. Dupuis, A. Lemaître, J. F. Guillemoles, S. Collin. Metal nanogrid for broadband multiresonant light-harvesting in ultrathin GaAs layers. ACS Photonics, 1, 878(2014).
[170] Y. Li, X. Yan, Y. Wu, X. Zhang, X. Ren. Plasmon-enhanced light absorption in GaAs nanowire array solar cells. Nanoscale Res. Lett., 10, 436(2015).
[171] X. L. Lin, C. W. Hsu, G. P. Wang. Frequency-selective omni-directional scattering of light by weakly disordered periodic planar arrays of dielectric particles. Opt. Express, 24, 23136(2016).
[172] Z. Wang, G. Duan, H. Duan. Optimization of the perfect absorber for solar energy harvesting based on the cone-like nanostructures. AIMS Energy, 9, 714(2021).
[173] M. K. Hedayati, M. Javaherirahim, B. Mozooni, R. Abdelaziz, A. Tavassolizadeh, V. S. Kiran Chakravadhanula, V. Zaporojtchenko, T. Strunkus, F. Faupel, M. Elbahri. Design of a perfect black absorber at visible frequencies using plasmonic metamaterials. Adv. Mater., 23, 5410(2011).
[174] A. Moreau, C. Ciracì, J. J. Mock, R. T. Hill, Q. Wang, B. J. Wiley, A. Chilkoti, D. R. Smith. Controlled-reflectance surfaces with film-coupled colloidal nanoantennas. Nature, 492, 86(2012).
[175] T. Reininger, F. Welker, M. V. Zeppelin. Sensors in position control applications for industrial automation. Sens. Actuat. A: Phys., 129, 270(2006).
[176] M. Indri, L. Lachello, I. Lazzero, F. Sibona, S. Trapani. Smart sensors applications for a new paradigm of a production line. Sensors, 19, 650(2019).
[177] K. Minoglou, N. Nelms, A. Ciapponi, H. Werber, S. Wittig, B. Leone, P. E. Crouzet. Infrared image sensor developments supported by the European space agency. Infrared Phys. Technol., 96, 351(2019).
[178] C. Liu, J. Lü, W. Liu, F. Wang, P. K. Chu. Overview of refractive index sensors comprising photonic crystal fibers based on the surface plasmon resonance effect [Invited]. Chin. Opt. Lett., 19, 102202(2021).
[179] H. H. Cho, T. K. Shih, H. C. Chao. A robust coverage scheme for UWSNs using the spline function. IEEE Sens. J., 16, 3995(2016).
[180] J. Aguzzi, M. M. Flexas, S. Flögel, C. Lo Iacono, M. Tangherlin, C. Costa, S. Marin, N. Bahamon, S. Martin, E. Fanell, R. Danovaro, S. Stefann, L. Thomsen, G. Riccobene, M. Hildebrand, I. Masmitja, J. Del Rio, E. B. Clark, A. Branch, P. Weiss, A. T. Klesh, M. P. Schodlok. Exo-ocean exploration with deep-sea sensor and platform technologies. Astrobiology, 20, 897(2020).
[181] Z. Bielecki, T. Stacewicz, J. Wojtas, J. Mikołajczyk, D. Szabra, A. Prokopiuk. Selected optoelectronic sensors in medical applications. Opto-Electron. Rev., 26, 122(2018).
[182] Y. Zhu, D. Liu, R. Grosu, X. Wang, H. Duan, G. Wang. A multi-sensor data fusion approach for atrial hypertrophy disease diagnosis based on characterized support vector hyperspheres. Sensors, 17, 2049(2017).
[183] S. T. Han, H. Peng, Q. Sun, S. Venkatesh, K. S. Chung, S. C. Lau, Y. Zhou, V. A. L. Roy. An overview of the development of flexible sensors. Adv. Mater., 29, 1700244(2017).
[184] J. Chen, H. Nie, C. J. Tang, Y. H. Cui, B. Yan, Z. Y. Zhang, Y. R. Kong, Z. J. Xu, P. G. Cai. Highly sensitive refractive-index sensor based on strong magnetic resonance in metamaterials. Appl. Phys. Express, 12, 052015(2019).
[185] N. Liu, M. Mesch, T. Weiss, M. Hentschel, H. Giessen. Infrared perfect absorber and its application as plasmonic sensor. Nano lett., 10, 2342(2010).
[186] Z. L. Deng, T. Fu, Z. B. Ouyang, G. P. Wang. Trimeric metasurfaces for independent control of bright and dark modes of Fano resonances. Appl. Phys. Lett., 108, 081109(2016).
[187] Z. Shen, M. Du. High-performance refractive index sensing system based on multiple Fano resonances in polarization-insensitive metasurface with nanorings. Opt. Express, 29, 28287(2021).
[188] N. Uddin, G. Q. Du, F. Chen, Y. Lu, Q. Yang, H. Bian, J. L. Yong, X. Hou. Fano resonance-assisted plasmonic trapping of nanoparticles. Plasmonics, 12, 627(2017).
[189] J. Y. Jung, J. Lee, J. H. Choi, D. G. Choi, J. H. Jeong. Enhancement of refractive index sensing for an infrared plasmonic metamaterial absorber with a nanogap. Opt. Express, 29, 22796(2021).
[190] Z. Yan, Q. Zhu, M. Wan, X. Lu, X. Pu, C. Tang, L. Yu. Graphene ultraviolet ultrahigh-Q perfect absorption for nanoscale optical sensing. Opt. Express, 28, 6095(2020).
[191] Z. Yan, X. Lu, W. Du, Z. Lv, C. Tang, P. Cai, P. Gu, J. Chen, Z. Yu. Ultraviolet graphene ultranarrow absorption engineered by lattice plasmon resonance. Nanotechnology, 32, 465202(2021).
[192] Y. H. Xian, Y. Cai, X. Y. Sun, X. F. Liu, Q. B. Guo, Z. X. Zhang, L. M. Tong, J. R. Qiu. Refractory plasmonic metal nitride nanoparticles for broadband near-infrared optical switches. Laser Photonics Rev., 13, 1900029(2019).
[193] S. L. Li, M. H. Yuan, W. J. Zhuang, X. Zhao, S. L. Tie, J. Xiang, S. Lan. Optically-controlled quantum size effect in a hybrid nanocavity composed of a perovskite nanoparticle and a thin gold film. Laser Photonics Rev., 15, 2000480(2021).
[194] X. W. Jiang, S. Wang, H. Wu. Metamaterial absorber with tunable absorption bandwidth based on vanadium dioxide. Acta Photonica Sin., 51, 0151124(2022).
[195] X. Liu, G. Liu, P. Tang, G. Fu, G. Du, Q. Chen, Z. Liu. Quantitatively optical and electrical-adjusting high-performance switch by graphene plasmonic perfect absorbers. Carbon, 140, 362(2018).
[196] Z. Q. Liu, J. Zhou, X. S. Liu, G. L. Fu, G. Q. Liu, C. J. Tang, J. Chen. High-Q plasmonic graphene absorbers for electrical switching and optical detection. Carbon, 166, 256(2020).
[197] X. M. Du, F. P. Yan, W. Wang, L. N. Zhang, Z. Y. Bai, H. Zhou, Y. F. Hou. A broadband switchable metamaterial absorber/reflector based on multi-laps graphene sheets in the terahertz band. IEEE Photonics J., 13, 4600208(2021).
[198] Y. B. Zhang, H. Liu, H. Cheng, J. G. Tian, S. Q. Chen. Multidimensional manipulation of wave fields based on artificial microstructures. Opto-Electron. Adv., 3, 200002(2020).
[199] Y. Shi, X. Chen, F. Lou, Y. Chen, M. Yan, L. Wosinski, M. Qiu. All-optical switching of silicon disk resonator based on photothermal effect in metal-insulator-metal absorber. Opt. Lett., 39, 4431(2014).
[200] Z. H. Han, Y. J. Cai. All-optical self-switching with ultralow incident laser intensity assisted by a bound state in the continuum. Opt. Lett., 46, 524(2021).
[201] S. W. Yu, Z. C. Li, W. W. Liu, H. Cheng, Y. B. Zhang, B. Y. Xie, W. Y. Zhou, J. G. Tian, S. Q. Chen. Tunable dual-band and high-quality-factor perfect absorption based on VO2-assisted metasurfaces. Opt. Express, 29, 31488(2021).
[202] B. Zeng, Z. Huang, A. Singh, Y. Yao, A. K. Azad, A. D. Mohite, A. J. Taylor, D. R. Smith, H. Chen. Hybrid graphene metasurfaces for high-speed mid-infrared light modulation and single-pixel imaging. Light Sci. Appl., 7, 51(2018).
[203] C. Pang, R. Li, Y. Zhang, Z. Li, N. Dong, L. Wu, H. Yu, J. Wang, F. Ren, F. Chen. Tailoring optical nonlinearities of LiNbO3 crystals by plasmonic silver nanoparticles for broadband saturable absorbers. Opt. Express, 26, 31276(2018).
[204] L. Zhao, F. Cai, L. Tong, Y. Yuan, W. Zhang, Y. Cai. Theoretical analysis of periodically poled LiNbO3 nonlinear mirror and its application in a passively mode-locked Nd:YSAG laser. Chin. Opt. Lett., 19, 091403(2021).
[205] B. Zhang, L. Wang, F. Chen. Recent advances in femtosecond laser processing of LiNbO3 crystals for photonic applications. Laser Photonics Rev., 14, 1900407(2020).
[206] Y. Tang, Y. Chen, H. Jiang, X. Chen. Proposal of switchable multiwavelength laser with continuously tunable spacing in MgO:APPLN waveguide. Chin. Opt. Lett., 11, 071301(2013).
[207] G. Liu, Q. Wu, X. Liu, X. Zhan, G. Fu, C. Tang, Z. Liu. High-performance electro-optic manipulation by plasmonic light absorber with nano-cavity field confinement. IEEE Photonics J., 13, 4600309(2021).
[208] Y. Jia, L. Wang, F. Chen. Ion-cut lithium niobate on insulator technology: recent advances and perspectives. Appl. Phys. Rev., 8, 011307(2021).
[209] N. Muhammad, Z. Ouyang, X. Tang, Q. Liu. Broadband wide-angle incident light absorption by metallic loop metasurfaces based on electro-optic substrate. IEEE Photon. Tech. Lett., 31, 1068(2019).
[210] X. Zhu, W. Yan, U. Levy, N. A. Mortensen, A. Kristensen. Resonant laser printing of structural colors on high-index dielectric metasurfaces. Sci. Adv., 3, e1602487(2017).
[211] P. Hosseini, C. D. Wright, H. Bhaskaran. An optoelectronic framework enabled by low-dimensional phase-change films. Nature, 511, 206(2014).
[212] S. Yokogawa, S. P. Burgos, H. A. Atwater. Plasmonic color filters for CMOS image sensor applications. Nano Lett., 12, 4349(2012).
[213] A. Tittl, A. K. U. Michel, M. Schäferling, X. Yin, B. Gholipour, L. Cui, M. Wuttig, T. Taubner, F. Neubrech, H. Giessen. A switchable mid-infrared plasmonic perfect absorber with multispectral thermal imaging capability. Adv. Mater., 27, 4597(2015).
[214] J. Guo, C. M. Huard, Y. Yang, Y. J. Shin, K. T. Lee, L. J. Guo. ITO-free, compact, color liquid crystal devices using integrated structural color filters and graphene electrodes. Adv. Opt. Mater., 2, 435(2014).
[215] H. Liu, H. Yang, Y. Li, B. Song, Y. Wang, Z. Liu, L. Peng, H. Lim, J. Yoon, W. Wu. Switchable all-dielectric metasurfaces for full-color reflective display. Adv. Opt. Mater., 7, 1801639(2019).
[216] C. S. Park, S. S. Lee. Vivid coloration and broadband perfect absorption based on asymmetric Fabry−Pérot nanocavities incorporating platinum. ACS Appl. Nano Mater., 4, 4216(2021).
[217] J. C. Zhao, Y. Zhou, Y. H. Huo, B. Gao, Y. G. Ma, Y. T. Yu. Flexible dynamic structural color based on an ultrathin asymmetric Fabry-Perot cavity with phase-change material for temperature perception. Opt. Express, 29, 23273(2021).
[218] G. H. Rui, C. C. Ding, B. Gu, Q. Q. Gan, Q. W. Zhan, Y. P. Cui. Symmetric Ge2Sb2Te5 based metamaterial absorber induced dynamic wide-gamut structural color. J. Opt., 22, 085003(2020).