Trans-Reflective Color Filters Based on a Phase Compensated Etalon Enabling Adjustable Color Saturation

Park, Chul‐Soon; Shrestha, Vivek Raj; Lee, Sang‐Shin; Choi, Duk‐Yong

doi:10.1038/srep25496

Cited by 73 publications

(55 citation statements)

References 38 publications

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“…In recent work, we theoretically demonstrated that noble metals can offer strong absorption in ultraviolet and visible (Vis) parts of the EM spectrum, while lossy metals can extend the upper-absorption edge up to the near-infrared (NIR) region [1]. Experimentally, these findings have been demonstrated in many recent research studies [17]- [44]. In one pioneering study, Mattiucci et al showed that impedance matched with thin metamaterials make metals absorbent [26].…”

Section: Lithography-free Multilayer Perfect Absorbersmentioning

confidence: 86%

“…we increase the insulator layer's refractive index, the refracted wave approaches normal incident, and consequently, the optical path difference for different incident angles decreases [99]. Another solution for this problem is to place an overlay on top of the cavity [17]. This sensitivity can be significantly suppressed in high-index, semiconductorbased cavity designs.…”

Section: Filteringmentioning

confidence: 99%

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Strong Interference in Planar, Multilayer Perfect Absorbers: Achieving High-Operational Performances in Visible and Near-Infrared Regimes

Ghobadi

Hajian

Bütün

et al. 2019

IEEE Nanotechnology Mag.

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Section: Lithography-free Multilayer Perfect Absorbersmentioning

confidence: 86%

Section: Filteringmentioning

confidence: 99%

Strong Interference in Planar, Multilayer Perfect Absorbers: Achieving High-Operational Performances in Visible and Near-Infrared Regimes

Ghobadi

Hajian

Bütün

et al. 2019

IEEE Nanotechnology Mag.

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“…Generally, the physical effect that is responsible for the colorization requires an adequate fabrication method. Deposition methods are used for thin dielectric and metallic films for etalons [Park et al 2016], Fabry-Perot cavities [Yang et al 2016], or thin-film stacks [Song et al 2017]. To obtain spatially-varying colorizations or non-uniform structures, additional dry or wet etching is usually required.…”

Section: Structural Colormentioning

confidence: 99%

Computational design of nanostructural color for additive manufacturing

2018

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Additive manufacturing has recently seen drastic improvements in resolution, making it now possible to fabricate features at scales of hundreds or even dozens of nanometers, which previously required very expensive lithographic methods. As a result, additive manufacturing now seems poised for optical applications, including those relevant to computer graphics, such as material design, as well as display and imaging applications. In this work, we explore the use of additive manufacturing for generating structural colors, where the structures are designed using a fabrication-aware optimization process. This requires a combination of full-wave simulation, a feasible parameterization of the design space, and a tailored optimization procedure. Many of these components should be re-usable for the design of other optical structures at this scale. We show initial results of material samples fabricated based on our designs. While these suffer from the prototype character of state-of-the-art fabrication hardware, we believe they clearly demonstrate the potential of additive nanofabrication for structural colors and other graphics applications.

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“…Thin film structures called "super absorbers" show a point of perfect absorption due to the complete suppression of transmission and reflection [10]. Structural color filters and reflectors with much better thermal stability, a higher color gamut, and lower angle sensitivity, compared to dye-based filters, have been realized [11,12]. Additionally, several groups have demonstrated the potential of cavity-enhanced PV [5,6,[13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Ultrathin Nano-Absorbers in Photovoltaics: Prospects and Innovative Applications

Götz¹,

Osterthun²,

Gehrke³

et al. 2020

Coatings

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Approaching the first terawatt of installations, photovoltaics (PV) are about to become the major source of electric power until the mid-century. The technology has proven to be long lasting and very versatile and today PV modules can be found in numerous applications. This is a great success of the entire community, but taking future growth for granted might be dangerous. Scientists have recently started to call for accelerated innovation and cost reduction. Here, we show how ultrathin absorber layers, only a few nanometers in thickness, together with strong light confinement can be used to address new applications for photovoltaics. We review the basics of this new type of solar cell and point out the requirements to the absorber layer material by optical simulation. Furthermore, we discuss innovative applications, which make use of the unique optical properties of the nano absorber solar cell architecture, such as spectrally selective PV and switchable photovoltaic windows.

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Trans-Reflective Color Filters Based on a Phase Compensated Etalon Enabling Adjustable Color Saturation

Cited by 73 publications

References 38 publications

Strong Interference in Planar, Multilayer Perfect Absorbers: Achieving High-Operational Performances in Visible and Near-Infrared Regimes

Strong Interference in Planar, Multilayer Perfect Absorbers: Achieving High-Operational Performances in Visible and Near-Infrared Regimes

Computational design of nanostructural color for additive manufacturing

Ultrathin Nano-Absorbers in Photovoltaics: Prospects and Innovative Applications

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