[1] |
Yang J, Zhang X, Zhang X, et al. Beyond the visible: Bioinspired infrared adaptive materials [J]. Advanced Materials, 2021, 33(14): 2004754. |
[2] |
Hu R, Xi W, Liu Y, et al. Thermal camouflaging metamaterials [J]. Materials Today, 2021, 45: 120-141. |
[3] |
Li, Y, Li W, Han T, et al. Transforming heat transfer with thermal metamaterials and devices [J]. Nature Reviews Materials, 2021, 6(6): 488-507. |
[4] |
桑建华, 王钢林. 固定翼飞行器红外隐身[J]. 隐身技术, 2005(1): 2-7 |
Sang Jianhua, Wang Ganglin. Infrared stealth of fixed wing aircraft [J]. Stealth Technology, 2005(1): 2-7. (in Chinese) |
[5] |
桑建华, 张宗斌. 红外隐身技术发展趋势[J]. 红外与激光工程, 2013, 42(1): 6 |
Sang Jianhua, Zhang Zongbin. Development trends of infrared stealth technology [J]. Infrared and Laser Engineering, 2013, 42(1): 14-19. (in Chinese) |
[6] |
韩义波, 杨新锋, 滕书华, 等. 激光与红外融合目标检测[J]. 红外与激光工程, 2018, 47(8): 7 |
Han Yibo, Yang Xinfeng, Teng Shuhua, et al. Detection of laser and infrared fusion target [J]. Infrared and Laser Engineering, 2018, 47(8): 0804005. (in Chinese) |
[7] |
桑建华, 张勇. 飞行器红外隐身技术[J]. 航空科学技术, 2011(5): 5-7 |
Sang Jianhua, Zhang Yong. Infrared stealth technology of air vehicles [J]. Aeronautical Science and Technology, 2011(5): 5-7. (in Chinese) |
[8] |
Bosquespadilla F J, Landy L N, Smith W K, et al. Perfect metamaterial absorber [J]. Physical Review Letters, 2008, 100(20): 207402. |
[9] |
Zhu H, Li Q, Tao C, Hong Y, et al. Multispectral camouflage for infrared, visible, lasers and microwave with radiative cooling [J]. Nature Communications, 2021, 12(1): 1805. |
[10] |
Jiang Xinpeng, Zhang Zhaojian, Ma Hansi, et al. Tunable mid-infrared selective emitter based on inverse design metasurface for infrared stealth with thermal management [J]. Optics Express, 2022, 30(11): 18250. |
[11] |
Macleod H A. Thin-Film Optical Filters[M]. 4th ed. France: CRC Press, 2010. |
[12] |
Park K C. The extreme values of reflectivity and the condition for zero reflection from thin dielectric film on metal [J]. Applied Optics, 1964, 3(7): 877. |
[13] |
Yeh P. Optical Waves in Layered Media[M]. US: Wiley-Interscience, 2005. |
[14] |
Prosvirnin S, Papasimakis N, Fedotov V, et al. Metamaterials and Plasmonics: Fundamentals, Modelling, Applications [M]. Netherlands: Springer Netherlands, 2009. |
[15] |
Maier S A. Plasmonics: Fundamentals and Applications[M]. US: Springer, 2007. |
[16] |
Maier S A, Zayats A V, Hanham S M. Active Plasmonics and Tuneable Plasmonic Metamaterials [M]. US: John Wiley Sons Inc, 2013. |
[17] |
Du Kaikai, Li Qiang, Lyu Yanbiao, et al. Control over emissivity of zero-static-power thermal emitters based on phase-changing material GST [J]. Light: Science and Application, 2017, 6(1): e16194. |
[18] |
Hosseini P, Wright C D, Bhaskaran H. An optoelectronic framework enabled by low-dimensional phase-change films [J]. Nature, 2014, 511(7508): 206-211. |
[19] |
Du K, Cai L, Luoet H, et al. Wavelength-tunable mid-infrared thermal emitters with a non-volatile phase changing material [J]. Nanoscale, 2018, 10(9): 4415-4420. |
[20] |
Wang, Q, Rogers E T F, Gholipour B, et al. Optically reconfigurable metasurfaces and photonic devices based on phase change materials [J]. Nature Photonics, 2015, 10(1): 60-65. |
[21] |
Feldmann J, Stegmaier M, Gruhler N, et al. Calculating with light using a chip-scale all-optical abacus [J]. Nature Communications, 2017, 8(1): 1256. |
[22] |
Nikolai V V, Gorden V, Thomas H. Effective medium theories for irregular fluffy structures: aggregation of small particles [J]. Applied Optics, 2007, 46(19): 4065-4072. |
[23] |
Jiang X, Chen D, Zhang Z, 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. |
[24] |
Jiang X, Zhang Z, Chen D, et al. Tunable multilayer-graphene-based broadband metamaterial selective absorber [J]. Applied Optics, 2020, 59(35): 11137-11145. |
[25] |
Jiang X, Yuan H, Chen D, et al. Metasurface based on inverse design for maximizing solar spectral absorption [J]. Advanced Optical Materials, 2021, 9(19): 2100575. |
[26] |
Molesky S, Lin Z, Piggott A Y, et al. Inverse design in nanophotonics [J]. Nature Photonics, 2018, 12(11): 659-670. |
[27] |
Huang J, Ma H, Chen D, et al. Digital nanophotonics: the highway to the integration of subwavelength-scale photonics [J]. Nanophotonics, 2021, 10(3): 1011-1030. |
[28] |
Ma W, Liu Z, Kudyshev Z A, et al. Deep learning for the design of photonic structures [J]. Nature Photonics, 2020, 15(2): 77-90. |
[29] |
Kudyshev Z A, Kildishev A V, Shalaev V M, et al. Machine-learning-assisted metasurface design for high-efficiency thermal emitter optimization [J]. Applied Physics Reviews, 2020, 7(2): 021407. |
[30] |
Liu D, Tan Y, Khoram E, et al. Training deep neural networks for the inverse design of nanophotonic structures [J]. ACS Photonics, 2018, 5(4): 1365-1369. |
[31] |
Zhou Y, Qin Z, Liang Z, et al. Ultra-broadband metamaterial absorbers from long to very long infrared regime [J]. Light: Science & Applications, 2021, 10(1): 138. |
[32] |
Ge Haonan, Xie Runzhang, Guo Jiaxiang, et al. Artificial micro- and nano-structure enhanced long and very long-wavelength infrared detectors [J]. Acta Physica Sinica, 2022, 71(11): 7-24. (in Chinese) |
[33] |
Jiang X, Yuan H, He X et al. Implementation of infrared camouflage with thermal management based on inverse design and hierarchical metamaterial [J]. Nanophotonics, 2023, 12(10): 1891-1902. |
[34] |
Zhang J K, Shi J M, Zhao D P, et al. Realization of compatible stealth material for infrared, laser and radar based on one-dimensional doping-structure photonic crystals [J]. Infrared Physics & Technology, 2017, 85: 62-65. |
[35] |
Kim T, Bae J Y, Lee N, et al. Hierarchical metamaterials for multispectral camouflage of infrared and microwaves [J]. Advanced Functional Materials, 2019, 29(10): 1807319. |
[36] |
Feng X, Xie X, Pu M, et al. Hierarchical metamaterials for laser-infrared-microwave compatible camouflage [J]. Optics Express, 2020, 28(7): 9445-9453. |
[37] |
Lee N, Lim J S, Chang I, et al. Flexible assembled metamaterials for infrared and microwave camouflage [J]. Advanced Optical Materials, 2022, 10(11): 2200448. |
[38] |
Kim J, Park C and Hahn J W. Metal-semiconductor-metal metasurface for multiband infrared stealth technology using camouflage color pattern in visible range [J]. Advanced Optical Materials, 2022, 10(6): 2101930. |
[39] |
Fan S. Thermal photonics and energy applications [J]. Joule, 2017, 1(2): 264-273. |
[40] |
Ou Kai, Yu Feilong, Chen Jin, et al. Research progress of broadband achromatic infrared metalens (Invited) [J]. Infrared and Laser Engineering, 2021, 50(1): 20211003. (in Chinese) |
[41] |
Peng L, Liu D, Cheng H, et al. A multilayer film based selective thermal emitter for infrared stealth technology [J]. Advanced Optical Materials, 2018, 6(23): 1801006. |
[42] |
Pan M, Huang Y, Li Q, et al. Multi-band middle-infrared-compatible camouflage with thermal management via simple photonic structures [J]. Nano Energy, 2020, 69: 104449. |
[43] |
Zhu H, Li Q, Zheng C, et al. High-temperature infrared camouflage with efficient thermal management [J]. Light Science & Application, 2020, 9: 60. |
[44] |
Yu K, Zhang W, Qian M, et al. Multiband metamaterial emitters for infrared and laser compatible stealth with thermal management based on dissipative dielectrics [J]. Photonics Research, 2023, 11: 290-298. |
[45] |
Xu Z, Luo H, Zhu H, et al. Nonvolatile optically reconfigurable radiative metasurface with visible tunability for anticounterfeiting [J]. Nano Letters, 2021, 21(12): 5269-5276. |
[46] |
Kim Y, Kim C, M Lee. Parallel laser printing of a thermal emission pattern in a phase-change thin film cavity for infrared camouflage and security [J]. Laser & Photonics Reviews, 2021, 16(3): 202100545. |
[47] |
Xu Z, Li Q, Du K, et al. Spatially resolved dynamically reconfigurable multilevel control of thermal emission [J]. Laser & Photonics Reviews, 2019, 14(1): 1900162. |
[48] |
Wei H, Gu J, Ren F, et al. Kirigami-inspired reconfigurable thermal mimetic device [J]. Laser & Photonics Reviews, 2022, 16(12): 2200383. |
[49] |
王义, 刘东青, 周峰, 等. 自适应伪装材料与技术研究进展, 中国材料进展, 2020, 39, 7. |
Wang Yi, Liu Dongqing, Zhou Feng, et al. Research progress of adaptive camouflage materials and technology [J]. Materials China, 2020, 39(5): 404-410. (in Chinese) |
[50] |
Qu Y, Li Q, Cai L, et al. Thermal camouflage based on the phase-changing material GST [J]. Light: Science & Applications, 2018, 7: 26. |
[51] |
Kim C, Kim Y, M. Lee. Laser-induced tuning and spatial control of the emissivity of phase-changing Ge2Sb2Te5 emitter for thermal camouflage [J]. Advanced Materials Technologies, 2022, 7(8): 2101349. |
[52] |
Liu Y, Song J, Zhao W, et al. Dynamic thermal camouflage via a liquid-crystal-based radiative metasurface [J]. Nanophotonics, 2020, 9(4): 855-863. |
[53] |
Chandra S, Franklin D, Cozart J, et al. Adaptive multispectral infrared camouflage [J]. ACS Photonics, 2018, 5(11): 4513. |
[54] |
Liu D, Ji H, Peng R, et al. Infrared chameleon-like behavior from VO2(M) thin films prepared by transformation of metastable VO2(B) for adaptive camouflage in both thermal atmospheric windows [J]. Solar Energy Materials and Solar Cells, 2018, 185: 210-217. |
[55] |
Tang K, Wang X, Dong K, et al. A thermal radiation modulation platform by emissivity engineering with graded metal–insulator transition [J]. Advanced Materials, 2020, 32(36): 1907071. |
[56] |
Salihoglu O, Uzlu H B, Yakar O, et al. Graphene-based adaptive thermal camouflage [J]. Nano Letters, 2018, 18(7): 4541-4548. |
[57] |
Ergoktas M S, Bakan G, Kovalska E, et al. Multispectral graphene-based electro-optical surfaces with reversible tunability from visible to microwave wavelengths [J]. Nature Photonics, 2021, 15(7): 493-498. |
[58] |
Song J, Huang S, Ma Y, et al. Radiative metasurface for thermal camouflage, illusion and messaging [J]. Optics Express, 2020, 28(2): 875-885. |
[59] |
Li M, Liu D, Cheng H, et al. Manipulating metals for adaptive thermal camouflage [J]. Science Advances, 2020, 6(22): 3494. |