Wideband mid-infrared thermal emitter based on stacked nanocavity metasurfaces

Tun Cao; Meng Lian; Kuan Liu; Xianchao Lou; Yaoming Guo; Dongming Guo

doi:10.1088/2631-7990/ac3bb1

Efficient thermal radiation in the mid-infrared (M-IR) region is of supreme importance for many applications including thermal imaging and sensing, thermal infrared light sources, infrared spectroscopy, emissivity coatings, and camouflage. The ability to control light makes metasurfaces an attractive platform for infrared applications. Recently, different metamaterials have been proposed to achieve high thermal radiation. To date, broadening the radiation bandwidth of a metasurface emitter (meta-emitter) has become a key goal to enable extensive applications. We experimentally demonstrate a broadband M-IR thermal emitter using stacked nanocavity metasurface consisting of two pairs of circular-shaped dielectric (Si₃N₄)-metal (Au) stacks. A high thermal radiation can be obtained by engineering the geometry of nanocavity metasurfaces. Such a meta-emitter provides wideband and broad angular absorptance of both p- and s-polarized light, offering a wideband thermal radiation with an average emissivity of more than 80% in the M-IR atmospheric window of 8-14 µm. The experimental illustration together with the theoretical framework establishes a basis for designing broadband thermal emitters, which, as anticipated, will initiate a promising avenue to M-IR sources.

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Dang J, Wang N and Atiyeh H K 2021 Review of dissolved CO and H₂ measurement methods for syngas fermentation Sensors 212165

Ando D J 2005 Infrared Spectroscopy:Fundamentals and Applications (Chichester:Wiley)

Zhou L, Tan Y, Ji D, Zhu B, Zhang P, Xu J, Gan Q, Yu Z and Zhu J 2016 Self-assembly of highly efficient, broadband plasmonic absorbers for solar steam generation Sci. Adv. 2 e1501227

Stanley R 2012 Plasmonics in the mid-infrared Nat. Photon. 6409-11

Yin X, Schäferling M, Michel A-K U, Tittl A, Wuttig M, Taubner T and Giessen H 2015 Active chiral plasmonics Nano Lett. 154255-60

Meriggi L, Steer M J, Ding Y, Thayne I G, MacGregor C, Ironside C N and Sorel M 2015 Enhanced emission from mid-infrared AlInSb light-emitting diodes with P-type contact grid geometry J. Appl. Phys. 117063101

Jackson S D 2012 Towards high-power mid-infrared emission from a fibre laser Nat. Photon. 6423-31

Gong Y, Wang Z, Li K, Uggalla L, Huang J, Copner N, Zhou Y, Qiao D and Zhu J 2017 Highly efficient and broadband mid-infrared metamaterial thermal emitter for optical gas sensing Opt. Lett. 424537-40

Dong W, Qiu Y, Zhou X, Banas A, Banas K, Breese M B, Cao T and Simpson R E 2018 Tunable mid-infrared phase-change metasurface Adv. Opt. Mater. 61701346

Gan Q, Bartoli F J and Kafafi Z H 2013 Plasmonic-enhanced organic photovoltaics:breaking the 10% efficiency barrier Adv. Mater. 252385-96

Greffet J-J, Carminati R, Joulain K, Mulet J-P, Mainguy S and Chen Y 2002 Coherent emission of light by thermal sources Nature 41661-4

Inoue T, de Zoysa M, Asano T and Noda S 2014 Realization of dynamic thermal emission control Nat. Mater. 13928-31

Schuller J A, Taubner T and Brongersma M L 2009 Optical antenna thermal emitters Nat. Photon. 3658

Roberts A S, Chirumamilla M, Thilsing-Hansen K, Pedersen K and Bozhevolnyi S I 2015 Near-infrared tailored thermal emission from wafer-scale continuous-film resonators Opt. Express 23 A1111-9

Tittl A, Michel A K U, Schäferling M, Yin X, Gholipour B, Cui L, Wuttig M, Taubner T, Neubrech F and Giessen H 2015 A switchable mid-infrared plasmonic perfect absorber with multispectral thermal imaging capability Adv. Mater. 274597-603

Liu X, Tyler T, Starr T, Starr A F, Jokerst N M and Padilla W J 2011 Taming the blackbody with infrared metamaterials as selective thermal emitters Phys. Rev. Lett. 107045901

Costantini D, Lefebvre A, Coutrot A-L, Moldovan-Doyen I, Hugonin J-P, Boutami S, Marquier F, Benisty H and Greffet J-J 2015 Plasmonic metasurface for directional and frequency-selective thermal emission Phys. Rev. Appl. 4014023

Liu X and Padilla W J 2016 Thermochromic infrared metamaterials Adv. Mater. 28871-5

Liang Y, Cui W, Li L, Yu Z, Peng W and Xu T 2019 Large-scale plasmonic nanodisk structures for a high sensitivity biosensing platform fabricated by transfer nanoprinting Adv. Opt. Mater. 71801269

Liu C-H, Chang Y-C, Norris T B and Zhong Z 2014 Graphene photodetectors with ultra-broadband and high responsivity at room temperature Nat. Nanotechnol. 9273-8

Mailoa J P, Akey A J, Simmons C B, Hutchinson D, Mathews J, Sullivan J T, Recht D, Winkler M T, Williams J S and Warrender J M 2014 Room-temperature sub-band gap optoelectronic response of hyperdoped silicon Nat. Commun. 51-8

Chou J B, Yeng Y X, Lee Y E, Lenert A, Rinnerbauer V, Celanovic I, Soljačić M, Fang N X, Wang E N and Kim S G 2014 Enabling ideal selective solar absorption with 2D metallic dielectric photonic crystals Adv. Mater. 268041-5

Xi J-Q, Schubert M F, Kim J K, Schubert E F, Chen M, Lin S-Y, Liu W and Smart J A 2007 Optical thin-film materials with low refractive index for broadband elimination of Fresnel reflection Nat. Photon. 1176-9

Cui Y, Fung K H, Xu J, Ma H, Jin Y, He S and Fang N X 2012 Ultrabroadband light absorption by a sawtooth anisotropic metamaterial slab Nano Lett. 121443-7

Zhou J, Kaplan A F, Chen L and Guo L J 2014 Experiment and theory of the broadband absorption by a tapered hyperbolic metamaterial array ACS Photonics 1618-24

Ji D, Song H, Zeng X, Hu H, Liu K, Zhang N and Gan Q 2014 Broadband absorption engineering of hyperbolic metafilm patterns Sci. Rep. 41-7

Jiang Z H, Yun S, Toor F, Werner D H and Mayer T S 2011 Conformal dual-band near-perfectly absorbing mid-infrared metamaterial coating ACS Nano 54641-7

Tang Y, Meng D, Liang Z, Qin Z, Shi X, Zhang Y, Xiong Y, Fan Y, Yang F and Zhang L 2020 An infrared metamaterial broadband absorber based on a simple titanium disk with high absorption and a tunable spectral absorption band Ann. Phys. 5322000145

Üstün K and Turhan-Sayan G 2016 Wideband long wave infrared metamaterial absorbers based on silicon nitride J. Appl. Phys. 120203101

Wu S-H, Chen M, Barako M T, Jankovic V, Hon P W, Sweatlock L A and Povinelli M L 2017 Thermal homeostasis using microstructured phase-change materials Optica 41390-6

Liu B, Gong W, Yu B, Li P and Shen S 2017 Perfect thermal emission by nanoscale transmission line resonators Nano Lett. 17666-72

Avitzour Y, Urzhumov Y A and Shvets G 2009 Wide-angle infrared absorber based on a negative-index plasmonic metamaterial Phys. Rev. B 79045131

Wang J, Fan C, Ding P, He J, Cheng Y, Hu W, Cai G, Liang E and Xue Q 2012 Tunable broad-band perfect absorber by exciting of multiple plasmon resonances at optical frequency Opt. Express 2014871-8

Dayal G and Ramakrishna S A 2012 Design of highly absorbing metamaterials for infrared frequencies Opt. Express 2017503-8

Palik E D 1998 Handbook of Optical Constants of Solids vol 3(New York:Academic)

Alici K B, Turhan A B, Soukoulis C M and Ozbay E 2011 Optically thin composite resonant absorber at the near-infrared band:a polarization independent and spectrally broadband configuration Opt. Express 1914260-7

Cao T, Zhang L, Simpson R E and Cryan M J 2013 Mid-infrared tunable polarization-independent perfect absorber using a phase-change metamaterial J. Opt. Soc. Am. B 301580-5

Tao H, Bingham C, Strikwerda A, Pilon D, Shrekenhamer D, Landy N, Fan K, Zhang X, Padilla W and Averitt R 2008 Highly flexible wide angle of incidence terahertz metamaterial absorber:design, fabrication, and characterization Phys. Rev. B 78241103

Barho F B, Gonzalez-Posada F, Cerutti L and Taliercio T 2020 Heavily doped semiconductor metamaterials for mid-infrared multispectral perfect absorption and thermal emission Adv. Opt. Mater. 81901502

Kats M A and Capasso F 2016 Optical absorbers based on strong interference in ultra-thin films Laser Photonics Rev. 10735-49

Cao T, Liu K, Tang Y, Deng J, Li K and Li G 2019 A high-index Ge₂Sb₂Te₅-based Fabry-Perot cavity and its application for third-harmonic generation Laser Photonics Rev. 131900063

Yang K, Wang J, Yao X, Lyu D, Zhu J, Yang Z, Liu B and Ren B 2021 Large-area plasmonic metamaterial with thickness-dependent absorption Adv. Opt. Mater. 92001375

Kelf T, Sugawara Y, Cole R, Baumberg J, Abdelsalam M, Cintra S, Mahajan S, Russell A and Bartlett P 2006 Localized and delocalized plasmons in metallic nanovoids Phys. Rev. B 74245415

Moreau A, Ciracì C, Mock J J, Hill R T, Wang Q, Wiley B J, Chilkoti A and Smith D R 2012 Controlled-reflectance surfaces with film-coupled colloidal nanoantennas Nature 49286-9

Alaee R, Menzel C, Huebner U, Pshenay-Severin E, Bin Hasan S, Pertsch T, Rockstuhl C and Lederer F 2013 Deep-subwavelength plasmonic nanoresonators exploiting extreme coupling Nano Lett. 133482-6

Dao T D, Chen K, Ishii S, Ohi A, Nabatame T, Kitajima M and Nagao T 2015 Infrared perfect absorbers fabricated by colloidal mask etching of Al-Al₂O₃-Al trilayers ACS Photonics 2964-70

Cao T, Wei C, Simpson R E, Zhang L and Cryan M J 2013 Rapid phase transition of a phase-change metamaterial perfect absorber Opt. Mater. Express 31101-10

Liu N, Mesch M, Weiss T, Hentschel M and Giessen H 2010 Infrared perfect absorber and its application as plasmonic sensor Nano Lett. 102342-8

Yee K 1966 Numerical solution of initial boundary value problems involving Maxwell's equations in isotropic media IEEE Trans. Antennas Propag. 14302-7

Zheng F, Chen Z and Zhang J 1999 A finite-difference time-domain method without the Courant stability conditions IEEE Microw. Guid. Wave Lett. 9441-3

Wideband mid-infrared thermal emitter based on stacked nanocavity metasurfaces

doi: 10.1088/2631-7990/ac3bb1

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通讯作者: 陈斌, bchen63@163.com

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