[1] Kim Y, Jung K, Cho J et al. Realizing vibrant and high-contrast reflective structural colors from lossy metals supporting dielectric gratings[J]. ACS Nano, 13, 10717-10726(2019).

[2] Yokogawa S, Burgos S P, Atwater H A. Plasmonic color filters for CMOS image sensor applications[J]. Nano Letters, 12, 4349-4354(2012).

[3] Liu F, Shi H, Zhu X et al. Tunable reflective color filters based on asymmetric Fabry-Perot cavities employing ultrathin Ge2Sb2Te5 as a broadband absorber[J]. Applied Optics, 57, 9040-9045(2018).

[4] Yang Z M, Wang Y S, Zhu X P et al. Periodic planar Fabry-Perot nanocavities with tunable interference colors based on filling density effects[J]. Applied Optics, 60, 551-557(2021).

[5] Ji C G, Lee K T, Xu T et al. Engineering light at the nanoscale: structural color filters and broadband perfect absorbers[J]. Advanced Optical Materials, 5, 1700368(2017).

[6] Chen Q, Wen L, Yang X G et al. Structural color technology for high pixel density image sensors[J]. Acta Optica Sinica, 41, 0823010(2021).

[7] Zhao Y J, Xie Z Y, Gu H C et al. Bio-inspired variable structural color materials[J]. Chemical Society Reviews, 41, 3297-3317(2012).

[8] Song M W, Wang D, Peana S et al. Colors with plasmonic nanostructures: a full-spectrum review[J]. Applied Physics Reviews, 6, 041308(2019).

[9] Yang W, Xiao S, Song Q et al. All-dielectric metasurface for high-performance structural color[J]. Nature Communications, 11, 1864(2020).

[10] Yang B, Cheng H, Chen S Q et al. Structural colors in metasurfaces: principle, design and applications[J]. Materials Chemistry Frontiers, 3, 750-761(2019).

[11] Pan H N, Chen Y H. Research progress in structural colors of nano resonant cell arrays[J]. The Journal of Light Scattering, 31, 11-18(2019).

[12] Højlund-Nielsen E, Clausen J, Mäkela T et al. Plasmonic colors: toward mass production of metasurfaces[J]. Advanced Materials Technologies, 1, 1600054(2016).

[13] Pryce I M, Aydin K, Kelaita Y A et al. Highly strained compliant optical metamaterials with large frequency tunability[J]. Nano Letters, 10, 4222-4227(2010).

[14] Tseng M L, Yang J, Semmlinger M et al. Two-dimensional active tuning of an aluminum plasmonic array for full-spectrum response[J]. Nano Letters, 17, 6034-6039(2017).

[15] Yoo S, Gwon T, Eom T et al. Multicolor changeable optical coating by adopting multiple layers of ultrathin phase change material film[J]. ACS Photonics, 3, 1265-1270(2016).

[16] Hosseini P, Wright C D, Bhaskaran H. An optoelectronic framework enabled by low-dimensional phase-change films[J]. Nature, 511, 206-211(2014).

[17] Shu F Z, Yu F F, Peng R W et al. Dynamic plasmonic color generation based on phase transition of vanadium dioxide[J]. Advanced Optical Materials, 6, 1700939(2018).

[18] Franklin D, Chen Y, Vazquez-Guardado A et al. Polarization-independent actively tunable colour generation on imprinted plasmonic surfaces[J]. Nature Communications, 6, 7337(2015).

[19] Kim I, Yun J, Badloe T et al. Structural color switching with a doped indium-gallium-zinc-oxide semiconductor[J]. Photonics Research, 8, 1409-1415(2020).

[20] Lee Y, Park M-K, Kim S et al. Electrical broad tuning of plasmonic color filter employing an asymmetric-lattice nanohole array of metasurface controlled by polarization rotator[J]. ACS Photonics, 4, 1954-1966(2017).

[21] Yoon G, So S, Kim M et al. Electrically tunable metasurface perfect absorber for infrared frequencies[J]. Nano Convergence, 4, 1-5(2017).

[22] Dong W L, Liu H L, Behera J K et al. Wide bandgap phase change material tuned visible photonics[J]. Advanced Functional Materials, 29, 1806181(2019).

[23] Zhang H F, Zhong A P, Wu Z M et al. Research progress on the thermochromic properties of vanadium dioxide thin films for smart windows[J]. Laser & Optoelectronics Progress, 58, 1500002(2021).

[24] Feigenbaum E, Diest K, Atwater H A. Unity-order index change in transparent conducting oxides at visible frequencies[J]. Nano Letters, 10, 2111-2116(2010).

[25] Yin K J. Research on the optical properties of PLZT and BST ferroelectric thin films[D]. Chengdu: University of Electronic Science and Technology of China(2006).

[26] Liu B, Shi J M, Lü X Y et al. Application of photonic crystalline infrared stealth films on surface of vehicle engine compartments[J]. Acta Photonica Sinica, 50, 0150003(2021).

[27] Qi D, Wang X, Cheng Y Z et al. Design and characterization of one-dimensional photonic crystals based on ZnS/Ge for infrared-visible compatible stealth applications[J]. Optical Materials, 62, 52-56(2016).

[28] Wang Z X, Cheng Y Z, Nie Y et al. Design and realization of one-dimensional double hetero-structure photonic crystals for infrared-radar stealth-compatible materials applications[J]. Journal of Applied Physics, 116, 054905(2014).