[1] |
Loewen E G, Popov E. Diffraction gGatings and Applications (Optical Science and Engineering)[M]. New York: CRC Press, 1997. |
[2] |
Koenderink A F, Alu A, Polman A. Nanophotonics: shrinking light-based technology [J]. Science, 2015, 348(6234): 516-521. |
[3] |
Collin S. Nanostructure arrays in free-space: optical properties and applications [J]. Reports on Progress in Physics, 2014, 77(12): 126402. |
[4] |
Smith D R, Pendry J B, Wiltshire M C K. Metamaterials and negative refractive index [J]. Science, 2004, 305(5685): 788-792. |
[5] |
Cai W, Chettiar U K, Kildishev A V, et al. Optical cloaking with metamaterials [J]. Nature Photonics, 2007, 1(4): 224. |
[6] |
Yu N, Capasso F. Flat optics with designer metasurfaces [J]. Nature Materials, 2014, 13(2): 139-150. |
[7] |
Ra’di Y, Sounas D L, Alù A. Metagratings: beyond the limits of graded metasurfaces for wave front control [J]. Physical Review Letters, 2017, 119(6): 067404. |
[8] |
Bonod N, Jérôme N. Diffraction gratings: from principles to applications in high-intensity lasers [J]. Advanced Optics Photonics, 2016, 8(1): 156-199. |
[9] |
Neviere M, Popov E. Light Propagation in Periodic Media: Differential Theory and Design[M]. Boca Raton: CRC Press, 2002. |
[10] |
Quaranta G, Basset G, Martin O J F, et al. Recent advances in resonant waveguide gratings [J]. Laser & Photonics Review, 2018, 12(9): 1800017.1-1800017.31. |
[11] |
Wang S S, Magnusson R. Theory and applications of guided-mode resonance filters [J]. Applied Optics, 1993, 32(14): 2606-2613. |
[12] |
Magnusson R, Wang S S. New principle for optical filters [J]. Applied Physical Letters, 1992, 61(9): 1022-1024. |
[13] |
Chang-Hasnain C J. High-contrast gratings as a new platform for integrated optoelectronics [J]. Semiconductor Science & Technology, 2010, 26(26): 014043. |
[14] |
Zhu Li, Yang Weijian, ChangHasnain C J. Very high efficiency optical coupler for silicon nanophotonic waveguide and single mode optical fiber [J]. Optics Exp, 2017, 25(15): 18462-18473. |
[15] |
Karagodsky V, Sedgwick F G, ChangHasnain C J. Theoretical analysis of subwavelength high contrast grating reflectors [J]. Optics Express, 2010, 18(16): 16973-16988. |
[16] |
Chang-Hasnain C J, Yang W. High-contrast gratings for integrated optoelectronics [J]. Advances in Optics & Photonics, 2012, 4(3): 379-440. |
[17] |
Popov V, Boust F, Burokur S N, et al. Constructing the near field and far field with reactive metagratings: study on the degrees of freedom [J]. Physical Review Applied, 2019, 11(2). |
[18] |
Ra’di, Y, Alù A. Reconfigurable metagratings [J]. ACS Photonics, 2018, 5(5): 1779-1785. |
[19] |
Fan Z, Shcherbakov M R, Allen M, et al. Perfect diffraction with multiresonant bianisotropic metagratings [J]. ACS Photonics, 2018, 5(11): 4303-4311. |
[20] |
Deng Zilan, Cao Yaoyu, Li Xiangping, et al. Multifunctional metasurface: from extraordinary optical transmission to extraordinary optical diffraction in a single structure: publisher's note [J]. Photonics Research, 2018, 6(7): 6. |
[21] |
Sell D, Yang J, Doshay S, et al. Large-angle, multifunctional metagratings based on freeform multimode geometries [J]. Nano Letters, 2017, 17(6): 3752-3757. |
[22] |
Sell D, Yang J, Wang E W, et al. Ultra-high-efficiency anomalous refraction with dielectric metasurfaces [J]. ACS Photonics, 2018, 5(6): 2402-2407. |
[23] |
Khaidarov E, Hao H, Paniaguadominguez R, et al. Asymmetric nanoantennas for ultrahigh angle broadband visible light bending [J]. Nano Letters, 2017, 17(10): 6267-6272. |
[24] |
Deng ZiLan, Deng Junhong, Zhuang Xin, et al. Facile metagrating holograms with broadband and extreme angle tolerance [J]. Light: Science & Applications, 2018, 7(1): 78. |
[25] |
Epstein A, Rabinovich O. Perfect anomalous refraction with metagratings[C]//European Conference on Antennas and Propagation, 2018. |
[26] |
Fu Yangyang, Shen Chen, Cao Yanyan, et al. Reversal of transmission and reflection based on acoustic metagratings with integer parity design [J]. Nature Communications, 2019, 10(1): 2326-2332. |
[27] |
Shi Tan, Wang Yujie, Deng Zilan, et al. All‐dielectric kissing-dimer metagratings for asymmetric high diffraction [J]. Advanced Optical Materials, 2019, 7(24): 1901389. |
[28] |
Liu Weinan, Chen Rui, Shi Weiyi, et al. Narrow-frequency sharp-angular filters using all-dielectric cascaded metagratings [J]. Nanophotonics, 2020: 20200141. |
[29] |
Zhang Lei, Mei Shengtao, Huang Kun, et al. Advances in full control of electromagnetic waves with metasurfaces [J]. Advanced Optical Materials, 2016, 4(6): 818-833. |
[30] |
Bonod N, Neauport J. Diffraction gratings: from principles to applications in high-intensity lasers [J]. Advances in Optics & Photonics, 2016, 8: 156-199. |
[31] |
Pierce J R. Coupling of modes of propagation [J]. Journal of Applied Physics, 1954, 25(2): 179-183. |
[32] |
Collin Stéphane. Nanostructure arrays in free-space: Optical properties and applications [J]. Reports on Progress in Physics Physical Society, 2014, 77(12): 126402. |
[33] |
Quaranta G, Basset G, Martin O J F, et al. Recent advances in resonant waveguide gratings [J]. Laser & Photonics Review, 2018, 12(9): 1800017. |
[34] |
Deng Zilan, Zhang Shuang, Wang Guoping. A facile grating approach towards broadband, wide-angle and high-efficiency holographic metasurfaces [J]. Nanoscale, 2016, 8: 1588. |
[35] |
Liu W, Kivshar Y S. Generalized Kerker effects in nanophotonics and meta-optics [Invited] [J]. Optics Express, 2018, 26(10): 13085-13105. |
[36] |
Chang-Hasnain C J, Yang W. High-contrast gratings for integrated optoelectronics [J]. Advances in Optics & Photonics, 2012, 4(3): 379-440. |
[37] |
Yang W. High-contrast gratings for integrated optoelectronics [J]. Advances in Optics and Photonics, 2012, 4(3): 379-440. |
[38] |
Wang Zhaorong, Zhang Bo, Deng Hui, et al. Dispersion engineering for vertical microcavities using subwavelength gratings [J]. Physical Review Letters, 2015, 114(7): 073601. |
[39] |
Liu Wenxing, Yu Tianbao, Sun Yong, et al. Highly efficient broadband wave plates using dispersion-engineered high-index-contrast subwavelength gratings [J]. Physical Review Applied, 2019, 11(6): 064005. |
[40] |
Epstein A, Rabinovich O. Perfect anomalous refraction with metagratings[C]//European Conference on Antennas and Propagation, 2018. |
[41] |
Popov V, Boust F, Burokur S N, et al. Controlling diffraction patterns with metagratings [J]. Physical Review Applied, 2018, 10(1): 011002. |
[42] |
Rabinovich O, Kaplon I, Reis J, et al. Experimental demonstration and in-depth investigation of analytically designed anomalous reflection metagratings [J]. Physical Review B, 2019, 99(12): 125101. |
[43] |
Epstein A, Rabinovich O. Unveiling the properties of metagratings via a detailed analytical model for synthesis and analysis [J]. Physical Review Applied, 2017, 8(5): 054037. |
[44] |
Rabinovich O, Epstein A. Analytical design of printed circuit board (pcb) metagratings for perfect anomalous reflection [J]. IEEE Transactions on Antennas and Propagation, 2018, 66(8): 4086-4095. |
[45] |
Popov V, Boust F, Burokur S N, et al. Constructing the near field and far field with reactive metagratings: study on the degrees of freedom [J]. Physical Review Applied, 2019, 11(2): 024074. |
[46] |
Chalabi H, Ra"Di Y, Sounas D L, et al. Efficient anomalous reflection through near-field interactions in metasurfaces [J]. Physical Review B, 2017, 96(7): 075432. |
[47] |
Patri A, Kenacohen S, Caloz C, et al. Large-angle, broadband and multifunctional directive waveguide scatterer gratings [J]. ACS Photonics, 2019, 6(12): 3298-3305. |
[48] |
Yang J, Sell D, Fan J A, et al. Freeform metagratings based on complex light scattering dynamics for extreme, high efficiency beam steering [J]. Annalen der Physik, 2018, 530(1): 1700302. |
[49] |
Liu W, Miroshnichenko A E. Beam steering with dielectric metalattices [J]. ACS Photonics, 2018, 5(5): 1733-1741. |
[50] |
Shi Weiyi, Deng Weimin, Liu Weinan, et al. Rectangular dielectric metagrating for high-efficiency diffraction with large-angle deflection [J]. Chinese Optics Letters, 2020, 18(7): 073601. |
[51] |
Neder V, Ra’di Y, Alù A, et al. Combined metagratings for efficient broad-angle scattering metasurface [J]. ACS Photonics, 2019, 6(4): 1010-1017. |
[52] |
Uleman F, Neder V, Cordaro A, et al. Resonant metagratings for spectral and angular control of light for colored rooftop photovoltaics [J]. ACS Applied Energy Materials, 2020, 3(4): 3150-3156. |
[53] |
Tiefenthaler K, Lukosz W. Integrated optical switches and gas sensors [J]. Optics Letters, 1984, 9: 137. |
[54] |
Norton S M, Morris G M, Erdogan T, et al. Experimental investigation of resonant-grating filter lineshapes in comparison with theoretical models [J]. Journal of The Optical Society of America A-Optics Image Science and Vision, 1998, 15(2): 464-472. |
[55] |
Yih J, Chu Y, Mao Y, et al. Optical waveguide biosensors constructed with subwavelength gratings [J]. Applied Optics, 2006, 45(9): 1938-1942. |
[56] |
Wawro D, Tibuleac S, Magnusson R, et al. Optical fiber endface biosensor based on resonances in dielectric waveguide gratings[C]//SPIE, 2000, 3911: 86-94. |
[57] |
Cunningham B T, Li P, Lin B, et al. Colorimetric resonant reflection as a direct biochemical assay technique [J]. Sensors and Actuators B-chemical, 2002, 81(2): 316-328. |
[58] |
Lin B, Qiu J, Gerstenmeier J, et al. A label-free optical technique for detecting small molecule interactions [J]. Biosensors and Bioelectronics, 2002, 17(9): 827-834. |
[59] |
Cunningham B T, Lin B, Qiu J, et al. A plastic colorimetric resonant optical biosensor for multiparallel detection of label-free biochemical interactions [J]. Sensors and Actuators B-chemical, 2002, 85(3): 219-226. |
[60] |
Cunningham B T, Li P, Schulz S C, et al. Label-free assays on the bind system [J]. Journal of Biomolecular Screening, 2004, 9(6): 481-490. |
[61] |
Fang Y, Ferrie A M, Fontaine N H, et al. Resonant waveguide grating biosensor for living cell sensing [J]. Biophysical Journal, 2006, 91(5): 1925-1940. |
[62] |
Omalley S M, Xie X, Frutos A G, et al. Label-free high-throughput functional lytic assays [J]. Journal of Biomolecular Screening, 2007, 12(1): 117-125. |
[63] |
Walia J, Dhindsa N, Khorasaninejad M, et al. Color generation and refractive index sensing using diffraction from 2d silicon nanowire arrays [J]. Small, 2014, 10(1): 144-151. |
[64] |
Hermannsson P G, Vannahme C, Smith C L, et al. Absolute analytical prediction of photonic crystal guided mode resonance wavelengths [J]. Applied Physics Letters, 2014, 105(7): 071103. |
[65] |
Wang Yongjin, Chen Jiajia, Shi Zheng, et al. Suspended membrane GaN gratings for refractive index sensing [J]. Applied Physics Express, 2014, 7(5): 052201. |
[66] |
Marciniak M, Gębski M, Dems M, et al. Subwavelength high contrast gratings as optical sensing elements [J]. Scientific Bulletin. Physics / Technical University of Łódź, 2017, 38: 61-70. |
[67] |
Sahoo P K, Sarkar S, Joseph J, et al. High sensitivity guided-mode-resonance optical sensor employing phase detection [J]. Scientific Reports, 2017, 7(1): 7607-7607. |
[68] |
Ganesh N, Zhang W, Mathias P C, et al. Enhanced fluorescence emission from quantum dots on a photonic crystal surface [J]. Nature Nanotechnology, 2007, 2(8): 515-520. |
[69] |
Ganesh N, Mathias P C, Zhang W, et al. Distance dependence of fluorescence enhancement from photonic crystal surfaces [J]. Journal of Applied Physics, 2008, 103(8): 083104. |
[70] |
Kano H, Kawata S. Two-photon-excited fluorescence enhanced by a surface plasmon. [J]. Optics Letters, 1996, 21(22): 1848-1850. |
[71] |
Wenseleers W, Stellacci F, Meyerfriedrichsen T, et al. Five orders-of-magnitude enhancement of two-photon absorption for dyes on silver nanoparticle fractal clusters [J]. Journal of Physical Chemistry B, 2002, 106(27): 6853-6863. |
[72] |
Soria S, Katchalski T, Teitelbaum E, et al. Enhanced two-photon fluorescence excitation by resonant grating waveguide structures [J]. Optics Letters, 2004, 29(17): 1989-1991. |
[73] |
André Selle, Kappel C, Bader M A, et al. Picosecond-pulse-induced two-photon fluorescence enhancement in biological material by application of grating waveguide structures [J]. Optics Letters, 2005, 30(13): 1683-1685. |
[74] |
Soria S, Badenes G, Bader M A, et al. Resonant double grating waveguide structures as enhancement platforms for two-photon fluorescence excitation [J]. Applied Physics Letters, 2005, 87(8): 081109. |
[75] |
Thayil A, Muriano A, Salvador J P, et al. Nonlinear immunofluorescent assay for androgenic hormones based on resonant structures [J]. Optics Express, 2008, 16(17): 13315-13322. |
[76] |
Nazirizadeh Y, Bog U, Sekula S, et al. Low-cost label-free biosensors using photonic crystals embedded between crossed polarizers [J]. Optics Express, 2010, 18(18): 19120-19128. |
[77] |
Nazirizadeh Y, Behrends V, Prosz A, et al. Intensity interrogation near cutoff resonance for label-free cellular profiling [J]. Scientific Reports, 2016, 6(1): 24685-24685. |
[78] |
Jahns S, Brau M, Meyer B, et al. Handheld imaging photonic crystal biosensor for multiplexed, label-free protein detection. [J]. Biomedical Optics Express, 2015, 6(10): 3724-3736. |
[79] |
Li H, Hsu W, Liu K, et al. A low cost, label-free biosensor based on a novel double-sided grating waveguide coupler with sub-surface cavities [J]. Sensors and Actuators B-chemical, 2015: 371-380. |
[80] |
Lin Y, Hsieh W, Chau L, et al. Intensity-detection-based guided-mode-resonance optofluidic biosensing system for rapid, low-cost, label-free detection [J]. Sensors and Actuators B-Chemical, 2017: 659-666. |
[81] |
Mcmahon J M, Henzie J, Odom T W, et al. Tailoring the sensing capabilities of nanohole arrays in gold films with Rayleigh anomaly-surface plasmon polaritons [J]. Optics Express, 2007, 15(26): 18119-18129. |
[82] |
Sun L B, Hu X L, Xu Y, et al. Influence of structural parameters to polarization-independent color-filter behavior in ultrathin Ag films [J]. Optics Communications, 2014, 333(15): 16-21. |
[83] |
Ebbesen T W, Lezec H J, Ghaemi H F, et al. Extraordinary optical transmission through sub-wavelength hole arrays [J]. Nature, 1998, 391(6668): 667-669. |
[84] |
Ghaemi H F, Thio T, Grupp D E, et al. Surface plasmons enhance optical transmission through subwavelength holes [J]. Physical Review B, 1998, 58(11): 6779-6782. |
[85] |
Chen Q, Cumming D R. High transmission and low color cross-talk plasmonic color filters using triangular-lattice hole arrays in aluminum films [J]. Optics Express, 2010, 18(13): 14056-14062. |
[86] |
Chen Q, Das D, Chitnis D, et al. A CMOS image sensor integrated with plasmonic colour filters [J]. Plasmonics, 2012, 7(4): 695-699. |
[87] |
Yokogawa S, Burgos S P, Atwater H A, et al. Plasmonic color filters for CMOS image sensor applications [J]. Nano Letters, 2012, 12(8): 4349-4354. |
[88] |
Chen Q, Chitnis D, Walls K, et al. CMOS photodetectors integrated with plasmonic color filters [J]. IEEE Photonics Technology Letters, 2012, 24(3): 197-199. |
[89] |
Burgos S P, Yokogawa S, Atwater H A. Color imaging via nearest neighbor hole coupling in plasmonic color filters integrated onto a complementary metal-oxide semiconductor image sensor [J]. ACS Nano, 2013, 7(11): 10038-10047. |
[90] |
Horie Y, Han S, Lee J, et al. Visible wavelength color filters using dielectric subwavelength gratings for backside-illuminated cmos image sensor technologies [J]. Nano Letters, 2017, 17(5): 3159-3164. |
[91] |
Mahani F F, Mokhtari A, Mehran M, et al. Dual mode operation, highly selective nanohole array-based plasmonic colour filters [J]. Nanotechnology, 2017, 28(38): 385203. |
[92] |
Tang L, Latif S, Miller D A, et al. Plasmonic device in silicon CMOS [J]. Electronics Letters, 2009, 45(13): 706-708. |
[93] |
Balaur E, Sadatnajafi C, Kou S S, et al. Continuously tunable, polarization controlled, colour palette produced from nanoscale plasmonic pixels [J]. Scientific Reports, 2016, 6(1): 28062-28062. |
[94] |
Yu Yan, Chen Qin, Wen Long, et al. Spatial optical crosstalk in CMOS image sensors integrated with plasmonic color filters [J]. Optics Express, 2015, 23(17): 21994-22003. |
[95] |
Knop K. Diffraction gratings for color filtering in the zero diffraction order [J]. Applied Optics, 1978, 17(22): 3598-3603. |
[96] |
Ganesh N, Xiang A, Beltran N B, et al. Compact wavelength detection system incorporating a guided-mode resonance filter [J]. Applied Physics Letters, 2007, 90(8): 81103. |
[97] |
Duempelmann L, Gallinet B, Novotny L, et al. Multispectral imaging with tunable plasmonic filters [J]. ACS Photonics, 2017, 4(2): 236-241. |
[98] |
Zeng B, Gao Y, Bartoli F J, et al. Ultrathin nanostructured metals for highly transmissive plasmonic subtractive color filters [J]. Scientific Reports, 2013, 3(1): 2840-2840. |
[99] |
Shrestha V R, Lee S, Kim E, et al. polarization-tuned dynamic color filters incorporating a dielectric-loaded aluminum nanowire array [J]. Scientific Reports, 2015, 5(1): 12450-12450. |
[100] |
Wang J, Fan Q, Zhang S, et al. Ultra-thin plasmonic color filters incorporating free-standing resonant membrane waveguides with high transmission efficiency [J]. Applied Physics Letters, 2017, 110(3): 31110. |
[101] |
Lee K, Jang J Y, Park S J, et al. Angle‐insensitive and CMOS-compatible subwavelength color printing [J]. Advanced Optical Materials, 2016, 4(11): 1696-1702. |
[102] |
Koirala I, Shrestha V R, Park C, et al. All dielectric transmissive structural multicolor pixel incorporating a resonant grating in hydrogenated amorphous silicon. [J]. Scientific Reports, 2017, 7(1): 13574. |
[103] |
Koirala I, Shrestha V R, Park C, et al. Polarization-controlled broad color palette based on an ultrathin one-dimensional resonant grating structure [J]. Scientific Reports, 2017, 7(1): 40073. |
[104] |
Crozier K B, Seo K, Park H, et al. controlling the light absorption in a photodetector via nanowire waveguide resonances for multispectral and color imaging [J]. IEEE Journal of Selected Topics in Quantum Electronics, 2018, 24(6): 1-12. |
[105] |
Seo K, Wober M, Steinvurzel P, et al. Multicolored vertical silicon nanowires [J]. Nano Letters, 2011, 11(4): 1851-1856. |
[106] |
Park H, Dan Y, Seo K, et al. Filter-free image sensor pixels comprising silicon nanowires with selective color absorption [J]. Nano Letters, 2014, 14(4): 1804-1809. |
[107] |
Yoon J, Kim K, Meyyappan M, et al. Optical characteristics of silicon-based asymmetric vertical nanowire photodetectors [J]. IEEE Transactions on Electron Devices, 2017, 64(5): 2261-2266. |
[108] |
Yue W, Gao S, Lee S, et al. Subtractive color filters based on a silicon-aluminum hybrid-nanodisk metasurface enabling enhanced color purity [J]. Scientific Reports, 2016, 6(1): 29756-29756. |
[109] |
Park C, Shrestha V R, Yue W, et al. Structural color filters enabled by a dielectric metasurface incorporating hydrogenated amorphous silicon nanodisks [J]. Scientific Reports, 2017, 7(1): 2556-2556. |
[110] |
Park C, Koirala I, Gao S, et al. Structural color filters based on an all-dielectric metasurface exploiting silicon-rich silicon nitride nanodisks [J]. Optics Express, 2019, 27(2): 667-679. |
[111] |
Miyata M, Nakajima M, Hashimoto T, et al. High-sensitivity color imaging using pixel-scale color splitters based on dielectric metasurfaces [J]. ACS Photonics, 2019, 6(6): 1442-1450. |
[112] |
Vashistha V, Vaidya G, Gruszecki P, et al. Polarization tunable all-dielectric color filters based on cross-shaped Si nanoantennas [J]. Scientific Reports, 2017, 7(1): 8092. |
[113] |
Yang Bo, Liu Wenwei, Li Zhancheng, et al. Polarization-sensitive structural colors with hue-and-saturation tuning based on all-dielectric nanopixels [J]. Advanced Optical Materials, 2018, 6(4): 1701009. |
[114] |
Dan A, Barshilia H C, Chattopadhyay K, et al. Solar energy absorption mediated by surface plasma polaritons in spectrally selective dielectric-metal-dielectric coatings: A critical review [J]. Renewable & Sustainable Energy Reviews, 2017, 79: 1050-1077. |
[115] |
Khodasevych I, Wang L, Mitchell A, et al. Micro- and nanostructured surfaces for selective solar absorption [J]. Advanced Optical Materials, 2015, 3(7): 852-881. |
[116] |
Cui Yanxia, He Yingran, Jin Yi, et al. Plasmonic and metamaterial structures as electromagnetic absorbers [J]. Laser & Photonics Reviews, 2014, 8(4): 495-520. |
[117] |
Zhao Bin, Hu Mingke, Ao Xianze, et al. Radiative cooling: A review of fundamentals, materials, applications, and prospects [J]. Applied Energy, 2019: 489-513. |
[118] |
Cui Yanxia, Fung Kung Hin, Xu Jun, et al. Ultrabroadband light absorption by a sawtooth anisotropic metamaterial sab [J]. Nano Letters, 2012, 12(3): 1443-1447. |
[119] |
Li Yuyin, Liu Zhengqi, Zhang Houjiao, et al. Ultra-broadband perfect absorber utilizing refractory materials in metal-insulator composite multilayer stacks [J]. Optics Express, 2019, 27(8): 11809-11818. |
[120] |
Li Junyu, Bao Li, Jiang Shun, et al. Inverse design of multifunctional plasmonic metamaterial absorbers for infrared polarimetric imaging [J]. Optics Express, 2019, 27(6): 8375-8386. |
[121] |
Lin H, Sturmberg B C, Lin K, et al. A 90-nm-thick graphene metamaterial for strong and extremely broadband absorption of unpolarized light [J]. Nature Photonics, 2019, 13(4): 270-276. |
[122] |
Luo M, Shen S, Zhou L, et al. Broadband, wide-angle, and polarization-independent metamaterial absorber for the visible regime [J]. Optics Express, 2017, 25(14): 16715-16724. |
[123] |
Han X, He K, He Z, et al. Tungsten-based highly selective solar absorber using simple nanodisk array [J]. Optics Express, 2017, 25(24): A1072-A1078. |
[124] |
Nielsen M G, Pors A, Albrektsen O, et al. Efficient absorption of visible radiation by gap plasmon resonators [J]. Optics Express, 2012, 20(12): 13311-13319. |
[125] |
Mann S A, Garnett E C. Resonant nanophotonic spectrum splitting for ultrathin multijunction solar cells [J]. ACS Photonics, 2015, 2(7): 816-821. |
[126] |
Chang C, Kortkamp W J, Nogan J, et al. High-temperature refractory metasurfaces for solar thermophotovoltaic energy harvesting [J]. Nano Letters, 2018, 18(12): 7665-7673. |
[127] |
Zhang Nan, Zhou Peihong Cheng Dengmu, et al. Dual-band absorption of mid-infrared metamaterial absorber based on distinct dielectric spacing layers [J]. Optics Letters, 2013, 38(7): 1125-1127. |
[128] |
Cattoni A, Ghenuche P, Haghirigosnet A M, et al. λ3/1000 plasmonic nanocavities for biosensing fabricated by soft uv nanoimprint lithography [J]. Nano Letters, 2011, 11(9): 3557-3563. |
[129] |
Zhao Bo, Wang Liping, Shuai Yong, et al. Thermophotovoltaic emitters based on a two-dimensional grating/thin-film nanostructure [J]. International Journal of Heat and Mass Transfer, 2013, 67: 637-645. |
[130] |
Zhang B, Hendrickson J, Guo J. Multispectral near-perfect metamaterial absorbers using spatially multiplexed plasmon resonance metal square structures [J]. Journal of the Optical Society of America B, 2013, 30(3): 656. |
[131] |
Zhang Nan, Zhou Peiheng, Wang Shuya, et al. Broadband absorption in mid-infrared metamaterial absorbers with multiple dielectric layers [J]. Optics Communications, 2015, 338: 388-392. |
[132] |
Wu C, Neuner B, Shvets G, et al. Large-area, wide-angle, spectrally selective plasmonic absorber [J]. Physical Review B, 2011, 84(7): 075102. |
[133] |
Lei L, Li S, Huang H, et al. Ultra-broadband absorber from visible to near-infrared using plasmonic metamaterial. [J]. Optics Express, 2018, 26(5): 5686-5693. |
[134] |
Kang S, Qian Z, Rajaram V, et al. Ultra‐narrowband metamaterial absorbers for high spectral resolution infrared spectroscopy [J]. Advanced Optical Materials, 2019, 7(2): 1801236.1-1801236.8. |
[135] |
Butun S, Aydin K. Structurally tunable resonant absorption bands in ultrathin broadband plasmonic absorbers [J]. Optics Express, 2014, 22(16): 19457-19468. |
[136] |
Liu X, Tyler T, Starr T, et al. Taming the blackbody with infrared metamaterials as selective thermal emitters. [J]. Physical Review Letters, 2011, 107(4): 045901. |
[137] |
Ma Wei, Wen Yongzheng, Yu Xiaomei, et al. Broadband metamaterial absorber at mid-infrared using multiplexed cross resonators [J]. Optics Express, 2013, 21(25): 30724-30730. |
[138] |
Grant J, Mccrindle I J, Li C, et al. Multispectral metamaterial absorber [J]. Optics Letters, 2014, 39(5): 1227-1230. |
[139] |
Aydin K, Ferry V E, Briggs R M, et al. Broadband polarization-independent resonant light absorption using ultrathin plasmonic super absorbers [J]. Nature Communications, 2011, 2(1): 517. |
[140] |
Li W, Guler U, Kinsey N, et al. Refractory plasmonics with titanium nitride: broadband metamaterial absorber [J]. Advanced Materials, 2014, 26(47): 7959-7965. |
[141] |
Nagarajan A, Vivek K, Shah M, et al. A broadband plasmonic metasurface superabsorber at optical frequencies: analytical design framework and demonstration [J]. Advanced Optical Materials, 2018, 6(16): 1800253. |
[142] |
Muhammad N, Tang X, Tao F, et al. Broadband polarization-insensitive absorption by metasurface with metallic pieces for energy harvesting application [J]. Materials Science and Engineering B-advanced Functional Solid-state Materials, 2019, 249: 114419. |
[143] |
Liu Jign, Chen Wei, Zheng Jiachun, et al. Wide-angle polarization-independent ultra-broadband absorber from visible to infrared [J]. Nanomaterials, 2019, 10(1): 27. |
[144] |
Wu Dong, Liu Chang, Liu Yumin, et al. Numerical study of an ultra-broadband near-perfect solar absorber in the visible and near-infrared region [J]. Optics Letters, 2017, 42(3): 450-453. |
[145] |
Liu Z, Tang P, Liu X, et al. Truncated titanium/semiconductor cones for wide-band solar absorbers [J]. Nanotechnology, 2019, 30(30): 305203. |
[146] |
Chi Kequn, Yang Liu, Liu Zhaolang, et al. Large-scale nanostructured low-temperature solar selective absorber [J]. Optics Letters, 2017, 42(10): 1891-1894. |
[147] |
Chi K, Yang L, He S, et al. Ultrathin nanostructured solar selective absorber based on a two-dimensional hemispherical shell array [J]. Applied Physics Letters, 2018, 112(6): 063903. |
[148] |
Zhang Z, Mo Y, Wang H, et al. High-performance and cost-effective absorber for visible and near-infrared spectrum based on a spherical multilayered dielectric–metal structure [J]. Applied Optics, 2019, 58(16): 4467-4473. |
[149] |
Ding Q, Barna S F, Jacobs K, et al. Feasibility analysis of nanostructured planar focusing collectors for concentrating solar power applications [J]. ACS Applied Energy Materials, 2018, 1(12): 6927-6935. |
[150] |
Wu Shangliang, Ye Yan, Jiang Zhouying, et al. Large‐area, ultrathin metasurface exhibiting strong unpolarized ultrabroadband absorption [J]. Advanced Optical Materials, 2019, 7(24): 1901162. |
[151] |
Yang Weijian, Sun Tianbo, Rao Yi, et al. High speed optical phased array using high contrast grating all-pass filters. [J]. Optics Express, 2014, 22(17): 20038-20044. |
[152] |
Zhang Ziying, Kang Ming, Zhang Xueqian, et al. Coherent perfect diffraction in metagratings [J]. Advanced Materials, 2020, 32(36): 2002341. |