Black metal thin films by deposition on dielectric antireflective moth-eye nanostructures

Christiansen, Alexander Bruun; Caringal, Gideon Peter; Clausen, Jeppe Sandvik; Grajower, Meir; Taha, Hesham; Levy, Uriel; Mortensen, N. Asger

doi:10.1038/srep10563

Cited by 35 publications

(29 citation statements)

References 23 publications

(24 reference statements)

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“…Thin dielectric multilayers lead to a 1D structuring in the direction normal to the interface. An alternative strategy consists of structuring the interface with 2D planar nanostructures 4 5 6 7 8 . This method is very interesting since it does not require different materials and the versatile shape of the nanostructuring offers additional optimizing parameters for better performances.…”

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confidence: 99%

Optimized 2D array of thin silicon pillars for efficient antireflective coatings in the visible spectrum

Proust

Fehrembach

Bedu

et al. 2016

Sci Rep

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Light reflection occuring at the surface of silicon wafers is drastically diminished by etching square pillars of height 110 nm and width 140 nm separated by a 100 nm gap distance in a square lattice. The design of the nanostructure is optimized to widen the spectral tolerance of the antireflective coatings over the visible spectrum for both fundamental polarizations. Angle and polarized resolved optical measurements report a light reflection remaining under 5% when averaged in the visible spectrum for both polarizations in a wide angular range. Light reflection remains almost insensitive to the light polarization even in oblique incidence.

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confidence: 99%

Optimized 2D array of thin silicon pillars for efficient antireflective coatings in the visible spectrum

Proust

Fehrembach

Bedu

et al. 2016

Sci Rep

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“…Black, that is absorption of all colours, is also still yet to be found using the methods reported here, but other methods such as randomly roughened and vertically tapered metal surfaces have achieved this feat [72,77]. …”

Section: All Metal Subtractivementioning

confidence: 99%

Metasurfaces-Based Absorption and Reflection Control: Perfect Absorbers and Reflectors

Badloe

Mun

Rho

2017

Journal of Nanomaterials

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In the past decade, the realisation of negative index materials has initiated extensive research into metamaterials. Perfect absorbers and reflectors are of particular interest as their usefulness is endless in a range of different fields and devices. Since it was originally shown that a device can achieve unity absorption of electromagnetic waves, it has become a hot area of research to develop perfect absorbers based on polarisation independence and incident angle independence, at a range of frequencies from microwave to optical ones. The amazing performance, flexibility, and tunability of these metamaterials will be discussed here, by presenting the different designs and working mechanisms that have been realised up to now. Their limitations and shortcomings will be addressed and future plans for perfect absorbers and reflectors will be suggested.

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“…[1,2] Nanopatterned metasurfaces can exhibit controllable spectral responses, enabling structure-based color printing, which is a promising high-resolution and fade-resistant alternative to pigment-based color. [3,4] In structural color generation, primitive geometries such as ellipsoids and polygons are commonly used as the nanostructure design. [5][6][7] With these geometries, the design process to attain specific properties is not particularly intuitive, although they can be parameterized according to their dimensions, e.g., radius, length, width, and orientation.…”

Section: Introductionmentioning

confidence: 99%

Applying Machine Learning to the Optics of Dielectric Nanoblobs

Trisno

Wang

et al. 2020

Advanced Photonics Research

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Dielectric nanostructures are the basic building blocks for photonic metasurfaces exhibiting designer optical responses. As their optical responses are nonintuitive, design procedures often consider only primitive geometries such as circles, ellipses, and rectangles. Despite these simplified geometries, achieving a target response still requires the forward design problem of solving Maxwell's equations to build a database of geometric parameters and their spectral responses. Herein, this work aims to leverage on the strength of deep neural networks (DNN) in image recognition to tackle the intractable inverse design problem of complex geometries, in which geometric parameters cannot be extracted. The work focuses on nanoblob geometries, i.e., irregular structures with rounded corners. When given a desired spectral response, the work investigates the ability of a well‐trained DNN in generating suitable geometries of the dielectric nanostructure and a corresponding source polarization.

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Black metal thin films by deposition on dielectric antireflective moth-eye nanostructures

Cited by 35 publications

References 23 publications

Optimized 2D array of thin silicon pillars for efficient antireflective coatings in the visible spectrum

Optimized 2D array of thin silicon pillars for efficient antireflective coatings in the visible spectrum

Metasurfaces-Based Absorption and Reflection Control: Perfect Absorbers and Reflectors

Applying Machine Learning to the Optics of Dielectric Nanoblobs

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