Fano resonant optical coatings platform for full gamut and high purity structural colors

ElKabbash, Mohamed; Hoffman, Nathaniel; Lininger, Andrew; Jalil, Sohail A.; Letsou, Theodore; Hinczewski, Michael; Strangi, Giuseppe; Chen, Guo

doi:10.1038/s41467-023-39602-2

Cited by 15 publications

(3 citation statements)

References 32 publications

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“…Recently, Mohamed et al designed a structure called Fabry-Perot resonance optical coatings (FROCs) [110] . They deposited a layer of absorbing dielectric material on an FP cavity, where the absorbing medium forms a broadband absorbing cavity with the first metal layer, and the lower three layers form an FP resonance serving as a narrowband absorbing cavity.…”

Section: Plasmonic-based Structural Colorsmentioning

confidence: 99%

“…(a) Integration of Si nanostructures into FP cavity for uniform cavity length structural color display (1), color tuning through the mixture of different nanostructures on a high-color-saturation display foundation (2), and easy achievement of polarization response by controlling the symmetry of nanostructures (3)[109] . (b) Schematic structure of FROCs formed by two coupled light absorbers (1), deposition of an absorbing medium on the FP cavity, coupling of the upper broadband mode with the lower FP resonance to form Fano resonance, resulting in vivid structural colors (2), (4), and exhibiting over 50°observation angle (3)[110] .…”

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confidence: 99%

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Recent progress on structural coloration

Li,

Hu,

Zeng

et al. 2024

Photonics Insights

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Structural coloration generates colors by the interaction between incident light and micro-or nanoscale structures. It has received tremendous interest for decades, due to advantages including robustness against bleaching and environmentally friendly properties (compared with conventional pigments and dyes). As a versatile coloration strategy, the tuning of structural colors based on micro-and nanoscale photonic structures has been extensively explored and can enable a broad range of applications including displays, anti-counterfeiting, and coating. However, scholarly research on structural colors has had limited impact on commercial products because of their disadvantages in cost, scalability, and fabrication. In this review, we analyze the key challenges and opportunities in the development of structural colors. We first summarize the fundamental mechanisms and design strategies for structural colors while reviewing the recent progress in realizing dynamic structural coloration. The promising potential applications including optical information processing and displays are also discussed while elucidating the most prominent challenges that prevent them from translating into technologies on the market. Finally, we address the new opportunities that are underexplored by the structural coloration community but can be achieved through multidisciplinary research within the emerging research areas.

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Section: Plasmonic-based Structural Colorsmentioning

confidence: 99%

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confidence: 99%

Recent progress on structural coloration

Li,

Hu,

Zeng

et al. 2024

Photonics Insights

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“…In general, typical thin-film coatings are composed of metal–dielectric–metal (MDM) cavities and produce colors through selective absorption of light. , Nevertheless, the main drawbacks associated with these MDM thin film coatings are of poor color purity and generate iridescent and distinct colors in the reflection and transmission modes. Lately, ElKabbash et al adeptly tackled these issues by introducing a novel type of thin-film coating consisting of a broadband and a narrowband absorber, which produces colors due to the generation of the asymmetric Fano resonance. − In a brief span, this color scheme has gained significant attention among researchers because of its numerous distinctive attributes, such as the ability to produce the same iridescence-free colors in both reflection and transmission modes, along with high resolution and purity. , Recently, dynamically tunable structural coloring was demonstrated by incorporating nonvolatile phase change materials (PCMs) into FROC, − as PCMs have received great attention due to their rapid switching speed, stable memory beyond the transition temperature, large refractive index contrast, and tunable optical responses across a wide range of wavelengths from ultraviolet to terahertz. ,− Although this discovery would bring many opportunities in the field of nanophotonics − including structural coloring, there are certain drawbacks associated with reflective tunable FROC-based color filters that require further research. The main shortcomings are (i) a broad and asymmetric Fano resonance spectrum hinders achieving a selective narrow reflection band in the visible spectrum, (ii) the presence of off-resonance reflections impacts the color purity, and (iii) absorption loss due to metal and lossy dielectric material hinders the attainment of highly reflective Fano resonance with narrow line width.…”

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confidence: 99%

Aperiodic Bragg Reflectors for Tunable High-Purity Structural Color Based on Phase Change Material

Jana,

Sreekanth,

Abdelraouf

et al. 2024

Nano Lett.

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Tunable thin-film coating-based reflective color displays have versatile applications including image sensors, camouflage devices, spatial light modulators, and intelligent windows. However, generating high-purity colors using such coatings have posed a challenge. Here, we reveal high-purity color generation using an ultralow-loss phase change material (Sb 2 S 3 )-based tunable aperiodic distributed Bragg reflector (A-DBR). By strategically adjusting the periodicity of the adjacent layers of A-DBRs, we realize a narrow photonic bandgap with high reflectivity to generate high-purity orange and yellow colors. In particular, we demonstrate an A-DBR with a large photonic bandgap tunability by changing the structural phase of Sb 2 S 3 layers from amorphous to crystalline. Moreover, we experimentally tailor multistate tunable colors through external optical stimuli. Unlike conventional nano thin-film coatings, our proposed approach offers an irradiance-free, narrowband, and highly reflective color band, achieving exceptional color purity by effectively suppressing reflections in off-color bands.

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Tunable and Non‐Invasive Printing of Transmissive Interference Colors with 2D Material Inks

Liu,

Huang,

et al. 2024

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Interference colors hold significant importance in optics and arts. Current methods for printing interference colors entail complex procedures and large‐scale printing systems for the scarcity of inks that exhibit both sensitivity and tunability to external fields. The production of highly transparent inks capable of rendering transmissive colors has presented ongoing challenges. Here, a type of paramagnetic ink based on 2D materials that exhibit polychrome in one magnetic field is invented. By precisely manipulating the doping ratio of magnetic elements within titanate nanosheets, the magneto‐optical sensitivity named Cotton–Mouton coefficient is engineerable from 728 to a record high value of 3272 m−1 T−2, with negligible influence on its intrinsic wide optical bandgap. Combined with the sensitive and controllable magneto‐responsiveness of the ink, modulate and non‐invasively print transmissive interference colors using small permanent magnets are precised. This work paves the way for preparing transmissive interference colors in an energy‐saving and damage‐free manner, which can expand its use in widespread areas.

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Fano resonant optical coatings platform for full gamut and high purity structural colors

Cited by 15 publications

References 32 publications

Recent progress on structural coloration

Recent progress on structural coloration

Aperiodic Bragg Reflectors for Tunable High-Purity Structural Color Based on Phase Change Material

Tunable and Non‐Invasive Printing of Transmissive Interference Colors with 2D Material Inks

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