Tunable plasmons in ultrathin metal films

Maniyara, Rinu Abraham; Rodrigo, Daniel; Yu, Renwen; Canet‐Ferrer, Josep; Ghosh, Dhriti Sundar; Yongsunthon, Ruchirej; Baker, David E.; Rezikyan, Aram; Abajo, F. Javier García de; Pruneri, Valerio

doi:10.1038/s41566-019-0366-x

Cited by 210 publications

(201 citation statements)

References 38 publications

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“…To ensure a smooth and clean surface, the Si x N y membranes were plasma cleaned using Argon-based reactive ion etching in the same vacuum chamber, immediately before Cu deposition. Following Maniyara et al 42 , the samples were then stored in air for one day to undergo oxidation. During this process, oxidization of Cu can lead to an increase of volume up to 68% (assuming formation of Cu 2 O 42 ).…”

Section: Methodsmentioning

confidence: 99%

Ultrathin 2 nm gold as impedance-matched absorber for infrared light

et al. 2020

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Thermal detectors are a cornerstone of infrared and terahertz technology due to their broad spectral range. These detectors call for efficient absorbers with a broad spectral response and minimal thermal mass. A common approach is based on impedance-matching the sheet resistance of a thin metallic film to half the free-space impedance. Thereby, one can achieve a wavelength-independent absorptivity of up to 50%. However, existing absorber films typically require a thickness of the order of tens of nanometers, which can significantly deteriorate the response of a thermal transducer. Here, we present the application of ultrathin gold (2 nm) on top of a surfactant layer of oxidized copper as an effective infrared absorber. An almost wavelength-independent and long-time stable absorptivity of 47(3)%, ranging from 2 μm to 20 μm, can be obtained. The presented absorber allows for a significant improvement of infrared/terahertz technologies in general and thermal detectors in particular.

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Section: Methodsmentioning

confidence: 99%

Ultrathin 2 nm gold as impedance-matched absorber for infrared light

et al. 2020

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“…[13] Dynamic color tuning (DCT) contrasts with conventional PCFs. The excitation wavelength of SPs can be dynamically controlled by way of grating period, [14][15][16][17][18][19][20] refractive index, [21][22][23] incidence angle, [24][25][26] polarization, [27][28][29][30] and chemical methods, [10,12,[31][32][33][34] providing features such as reduction of light loss, continuous input/output, and wavelength management.…”

Section: Stretchable and High-adhesive Plasmonic Metasheet Using Al Smentioning

confidence: 99%

Stretchable and High‐Adhesive Plasmonic Metasheet Using Al Subwavelength Grating Embedded in an Elastomer Nanosheet

Koike

Fujie

Sawada

et al. 2020

Advanced Optical Materials

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Plasmonic metasurfaces have attracted much attention for use in device applications over the past decade. Dynamic color tuning (DCT), where the displacement of periodic nanostructures is controlled to generate different colors in real time, is one of the great possibilities of plasmonic metasurfaces for optical strain sensors or display devices. In this study, an Al metasurface embedded in an elastomer nanosheet with film thickness 400 nm is fabricated by means of sacrificial release using a polyvinyl alcohol sacrificial layer. This plasmonic metasheet shows not only the seven colors produced by surface plasmons, but also DCT by stretching the elastomer nanosheet. Each pixel, designed with a grating period of 300–600 nm, emits the bright colors expected in electromagnetic simulation. Moreover, stretching the plasmonic metasheet demonstrates DCT from 495 to 660 nm in the visible light range. The freestanding metasheet with maximum thickness 400 nm may be easily integrated into any active device by post‐processing transfer. Stretching the metasheet requires an estimated × 10−3 lower force than previously reported for plasmonic metasurfaces, owing to a film thickness of only several hundreds of nanometers. These results facilitate the realization of microdevices with novel capabilities based on plasmonic metamaterials.

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“…Maniyara et al 79 developed a method to evaporate ultrathin gold¯lms of thickness less than 5 nm using copper seeding. Such¯lms are su±ciently thin to exhibit e®ects similar to those found in 2D metallic materials like graphene.…”

Section: Plasmons In Ultrathin Noble Metalsmentioning

confidence: 99%

Hybrid Plasmonics and Two-Dimensional Materials: Theory and Applications

Sebek

Elbana

Nemati

et al. 2020

J. Mol. Eng. Mater.

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The inherent thinness of two-dimensional 2D materials limits their efficiency of light-matter interactions and the high loss of noble metal plasmonic nanostructures limits their applicability. Thus, a combination of 2D materials and plasmonics is highly attractive. This review describes the progress in the field of 2D plasmonics, which encompasses 2D plasmonic materials and hybrid plasmonic-2D materials structures. Novel plasmonic 2D materials, plasmon-exciton interaction within 2D materials and applications comprising sensors, photodetectors and, metasurfaces are discussed.

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Tunable plasmons in ultrathin metal films

Cited by 210 publications

References 38 publications

Ultrathin 2 nm gold as impedance-matched absorber for infrared light

Ultrathin 2 nm gold as impedance-matched absorber for infrared light

Stretchable and High‐Adhesive Plasmonic Metasheet Using Al Subwavelength Grating Embedded in an Elastomer Nanosheet

Hybrid Plasmonics and Two-Dimensional Materials: Theory and Applications

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