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Multiple Tunable Hyperbolic Resonances in Broadband Infrared Carbon-Nanotube Metamaterials

John Andris Roberts, Po‐Hsun Ho, Shang‐Jie Yu, Xiangjin Wu, Yue Luo, William L. Wilson, Abram L. Falk, Jonathan A. Fan

2020Physical Review Applied21 citationsDOIOpen Access PDF

Abstract

Aligned densely packed carbon-nanotube metamaterials prepared using vacuum filtration are an emerging infrared nanophotonic material. We report multiple hyperbolic plasmon resonances, together spanning the mid-infrared, in individual resonators made from aligned and densely packed carbon nanotubes. In a near-field scanning optical microscopy (NSOM) imaging study of nanotube metamaterial resonators, we observe distinct deeply subwavelength field profiles at the fundamental and higher-order resonant frequencies. The wafer-scale area of the nanotube metamaterials allows us to combine this near-field imaging with a systematic far-field spectroscopic study of the scaling properties of many resonator arrays. Thorough theoretical modeling agrees with these measurements and identifies the resonances as higher-order Fabry-Perot (FP) resonances of hyperbolic waveguide modes. Nanotube resonator arrays show broadband extinction from 1.5--10 \textmu{}m and reversibly switchable extinction in the 3--5 \textmu{}m atmospheric transparency window through the coexistence of multiple modes in individual ribbons. Broadband carbon-nanotube metamaterials supporting multiple resonant modes are a promising candidate for ultracompact absorbers, tunable thermal emitters, and broadband sensors in the mid-infrared.

Topics & Concepts

MetamaterialCarbon nanotubeMaterials scienceResonatorInfraredOptoelectronicsNear-field scanning optical microscopeBroadbandNanophotonicsNanotubeOpticsNanotechnologyPhysicsOptical microscopeScanning electron microscopeThermal Radiation and Cooling TechnologiesPlasmonic and Surface Plasmon ResearchMetamaterials and Metasurfaces Applications