基于InP、InAs和InSb材料的超宽带红外线吸收器
赵晨, 薛文瑞, 陈曦, 陈岳飞, 李昌勇. 基于InP、InAs和InSb材料的超宽带红外线吸收器[J]. 量子光学学报, 2018, 24(4): 420.
ZHAO Chen, XUE Wen-rui, CHEN Xi, CHEN Yue-fei, LI Chang-yong. Ultra-Broadband Infrared Absorber Based on InP,InAs and InSb Materials[J]. Acta Sinica Quantum Optica, 2018, 24(4): 420.
[1] Barnes W L,Dereux A,Ebbesen T W.Surface Plasmon Subwavelength Optics[J].Nature,2003,424(6950):824-830.DOI:101038/nature01937.
[2] Raether H.Surface Plasmons on Smooth and Rough Surfaces and on Gratings[M].Springer Berlin Heidelberg,1988,111(1):1-133.
[3] Schurig D,Mock J J,Justice B J,et al.Metamaterial Electromagnetic Cloak at Microwave Frequencies[J].Science,2006,314(5801):977-980.DOI:101126/science.1133628.
[4] Pendry J B,Schurig D,Smith D R.Controlling Electromagnetic Fields[J].Science,2006,312(5781):1780-1782.DOI:101126/science.1125907.
[5] Meng F Y,Zhang K,Zhang F,et al.Reconfigurable Subwavelength Waveguide Based on Magnetic Metamaterial[J].Applied Physics A,2011,102(3):509-515.DOI:101007/s00339-010-6177-z.
[6] Dai D,Xu P,Chen P,et al.Low-loss Ultracompact Transverse-magnetic-pass Polarizer with a Silicon Subwavelength Grating Waveguide[J].Optics Letters,2014,39(15):4514-4517.DOI:101364/OL.39004514.
[7] Hao X,Liu X,Kuang C,et al.Far-field Super-resolution Imaging Using Near-field Illumination by Micro-fiber[J].Applied Physics Letters,2013,102(1):013104-013104-4.DOI:101063/14773572.
[8] Kim K,Yajima J,Oh Y,et al.Imaging:Nanoscale Localization Sampling Based on Nanoantenna Arrays for Super-resolution Imaging of Fluorescent Monomers on Sliding Microtubules (Small 6/2012)[J].Small,2012,8(6):786-786.DOI:101002/smll.201101840.
[9] Palakal M,Mukhopadhyay S,Mostafa J,et al.An Intelligent Biological Information Management System[C].Bioinformatics,2002:159-163.DOI:101145/508791508824.
[10] Tang X,Feng Q,Wang J,et al.Clustering Based on Multiple Biological Information:Approach for Predictingprotein Complexes[J].Iet Systems Biology,2013,7(5):223-230.DOI:101049/iet-syb.20120052.
[12] Wu C,Iii B N,John J,et al.Large-area,Wide-angle,Spectrally Selective Plasmonic Absorber[J].Physical Review B Condensed Matter,2011,84(7):173-177.DOI:101016/j.talanta.201802044.
[13] Zhong M,Liu S J,Xu B L,et al.Single-band High Absorption and Coupling Between Localized Surface Plasmons Modes in a Metamaterials Absorber[J].Optical Materials,2017,72:283-288.DOI:101016/j.optmat.201706019.
[14] Chern R L,Hong W T.Nearly Perfect Absorption in Intrinsically Low-loss Grating Structures[J].Optics Express,2011,19(9):8962-8972.DOI:101364/OE.19008962.
[15] Liao Y L,Zhao Y.A Multiband Absorber Based on Multipolar Plasmon Excitation[J].Optik-International Journal for Light and Electron Optics,2014,125(13):3037-3039.DOI:101016/j.ijleo.201312017.
[16] Zhai Y,Chen G,Xu J,et al.Multiple-band Perfect Absorbers Based on the Combination of Fabry-Perot Resonance and the Gap Plasmon Resonance[J].Optics Communications,2017,399:28-33.DOI:101016/j.optcom.201704041.
[17] 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.DOI:101038/ncomms1528.
[18] Zhong M.Localized Surface Plasmon Resonnance Induced Terahertz Broad Absorption Band[J].Optics Communications,2015,356:607-611.DOI:101016/j.optcom.201508059.
[19] Bonod N,Tayeb G,Maystre D,et al.Total Absorption of Light by Lamellar Metallic Gratings[J].Optics Express,2008,16(20):15431-15438.DOI:101364/OE.16015431.
[20] Song J,Lu L,Cheng Q,et al.Surface Plasmon-Enhanced Optical Absorption in Monolayer MoS 2,with One-Dimensional Au Grating[J].Journal of Quantitative Spectroscopy & Radiative Transfer,2018,211:138-143.DOI:101016/j.jqsrt.201802036.
[21] Kats M A,Blanchard R,Genevet P,et al.Nanometre Optical Coatings Based on Strong Interference Effects in Highly Absorbing Media[J].Nature Materials,2013,12(1):20-24.DOI:101038/NMAT3443.
[22] Hedayati M K,Javaherirahim M,Mozooni B,et al.Design of a Perfect Black Absorber at Visible Frequencies Using Plasmonic Metamaterials[J].Advanced Materials,2011,23(45):5409-5409.DOI:101002/adma.201102646.
[23] Chen C,Sheng Y,Wang J.Computed a Multiple Band Metamaterial Absorber and Its Application Based on the Figure of Merit Value[J].Optics Communications,2017,406:145-150.DOI:101016/j.optcom.201706009.
[24] Qian Z,Yang D,Wang W.Terahertz Modulation Based on Surface Plasmon Resonance by Self-gated Graphene[J].Optics Communications,2018,414:52-58.DOI:101016/j.optcom.201712039.
[25] Dasri T,Chingsungnoen A.Surface Plasmon Resonance Enhanced Light Absorption and Wavelength Tuneable in Gold-coated Iron Oxide Spherical Nanoparticle[J].Journal of Magnetism & Magnetic Materials,2018,456:368-371.DOI:101016/j.jmmm.201802066.
[26] Liu L,He Z,Zhao Y,et al.Modulation of the Composition and Surface Morphology of Expanded Graphite/Fe/Fe3O4 Composites for Plasmon Resonance-enhanced Microwave Absorption[J].Journal of Alloys and Compounds,2018,4.DOI:101016/j.jallcom.201804212.
[27] Wu D,Liu Y,Yu Z,et al.Wide-angle,Polarization-insensitive and Broadband Absorber Based on Eight-fold Symmetric SRRs Metamaterial[J].Optics Communications,2016,380:221-226.DOI:101016/j.optcom.201606023.
[28] Xing R,Jian S.A Dual-band THz Absorber Based on Graphene Sheet and Ribbons[J].Optics & Laser Technology,2018,100:129-132.DOI:101016/j.optlastec.201710003.
[29] Aslan E,Kaya S,Aslan E,et al.Polarization Insensitive Plasmonic Perfect Absorber with Coupled Antisymmetric Nanorod Array[J].Sensors & Actuators B Chemical,2017,243:617-625.DOI:101016/j.snb.201612030.
[30] Hao J,Wang J,Liu X,et al.High Performance Optical Absorber Based on a Plasmonic Metamaterial[J].Applied Physics Letters,2010,96(25):251104-251104-3.DOI:101063/13442904.
[31] Zhao D,Qiu M,Li Q,et al.Double-sided Polarization-independent Plasmonic Absorber at Near-infrared Region[J].Optics Express,2013,21(11):13125-13133.DOI:101364/OE.21013125.
[32] Zare M S,Nozhat N,Rashiditabar R.Tunable Graphene Based Plasmonic Absorber with Grooved Metal Film in Near Infrared Region[J].Optics Communications,2017,398:56-61.DOI:101016/j.optcom.201704025.
[33] Aslan E,Aslan E,Turkmen M,et al.Experimental and Numerical Characterization of a Mid-infrared Plasmonic Perfect Absorber for Dual-band Enhanced Vibrational Spectroscopy[J].Optical Materials,2017,73:213-222.DOI:101016/j.optmat.201708023.
[34] Yuan Wan,Yashuai An,Zhi Tao,et al.Manipulation of Surface Plasmon Resonance of a Graphene-based Au Aperture Antenna in Visible and Near-infrared Regions[J].Optics Communications,2018,410:733-739.DOI:101016/j.optcom.201711042.
[35] Vliet T V D,Vece M D.Shifting the Aluminum Nanoparticle Plasmon Resonance to the Visible with SiN and a-Si Thin Films[J].Thin Solid Films,2016,603:404-407.DOI:101016/j.tsf.201602061.
[36] Monnier G F.A Review of Infrared Spectroscopy in Microarchaeology:Methods,Applications,and Recent Trends[J].Journal of Archaeological Science Reports,2018(18):806-823.DOI:101016/j.jasrep.201712029.
[37] Marcelli A,Cricenti A,Kwiatek W M,et al.Biological Applications of Synchrotron Radiation Infrared Spectromicroscopy[J].Biotechnology Advances,2012,30(6):1390-1404.DOI:101016/j.biotechadv.201202012.
[38] Sousa E,Vardasca R,Teixeira S,et al.A Review on the Application of Medical Infrared Thermal Imaging in Hands[J].Infrared Physics & Technology,2017,86:315-323.DOI:101016/j.infrared.201707020.
[39] Xue Wenrui,Chen Xi,Peng Yanling,et al.Grating-type Mid-infrared Light Absorber Based on Silicon Carbide Material[J].Optics Express,2016,24(20):22596-22605.DOI:101364/OE.24022596.
[40] Toprak A,Ghobadi A,Butun B,et al.Visible Light Nearly Perfect Absorber:an Optimum Unit Cell Arrangement for Near Absolute Polarization Insensitivity[J].Opt Express,2017,25(22):27624-27634.DOI:101364/OE.25027624.
[41] Wu D,Liu C,Liu Y,et al.Numerical Study of an Ultra-broadband Near-perfect Solar Absorber in the Visible and Near-infrared Region[J].Opt Lett,2017,42(3):450-453.DOI:101364/OL.42000450.
[42] Ji D,Song H,Zeng X,et al.Broadband Absorption Engineering of Hyperbolic Metafilm Patterns[C].Lasers and Electro-Optics.IEEE,2014,4(3):1-2.DOI:101038/srep04498.
[43] Ding F,Jin Y,Li B,et al.Ultrabroadband Strong Light Absorption Based on Thin Multilayered Metamaterials[J].Laser & Photonics Reviews,2015,8(6):946-953.DOI:101002/lpor.201400157.
[44] Lin Y,Cui Y,Ding F,et al.Tungsten Based Anisotropic Metamaterial as an Ultra-broadband Absorber[J].Optical Materials Express,2016,7(2):606-617.DOI:101364/OME.7000606.
[45] Wu S D,Guo L W,Li Z H,et al.Effect of the Low-temperature Buffer Thickness on Quality of InSb Grown on GaAs Substrate by Molecular Beam Epitaxy[J].Journal of Crystal Growth,2005,277(1):21-25.DOI:101016/j.jcrysgro.200412141.
[46] Khan M Z M,Ng T K,Ooi B S.Self-assembled InAs/InP Quantum Dots and Quantum Dashes:Material Structures and Devices[J].Progress in Quantum Electronics,2014,38(6):237-313.DOI:101016/j.pquantelec.201411001.
[47] Korobkin D,Urzhumov Y,Shvets G.Enhanced Near-field Resolution in Midinfrared using Metamaterials[J].Journal of the Optical Society of America B,2006,23(3):468-478.DOI:101364/JOSAB.23000468.
[48] Hass M,Henvis B W.Infrared Lattice Reflection Spectra of Ⅲ-Ⅴ Compound Semiconductors[J].Journal of Physics & Chemistry of Solids,1962,23(8):1099-1104.DOI:101016/0022-3697(62)90127-0.
[49] Sanderson R B.Far Infrared Optical Properties of Indium Antimonide[J].Journal of Physics & Chemistry of Solids,1965,26(5):803-810.DOI:101016/0022-3697(65)90255-6.
赵晨, 薛文瑞, 陈曦, 陈岳飞, 李昌勇. 基于InP、InAs和InSb材料的超宽带红外线吸收器[J]. 量子光学学报, 2018, 24(4): 420. ZHAO Chen, XUE Wen-rui, CHEN Xi, CHEN Yue-fei, LI Chang-yong. Ultra-Broadband Infrared Absorber Based on InP,InAs and InSb Materials[J]. Acta Sinica Quantum Optica, 2018, 24(4): 420.
PDF全文
