Color filters featuring high transmission efficiency and broad bandwidth based on resonant waveguide-metallic grating

Nguyen-Huu, Nghia; Lo, Yu-Lung; Chen, Yubin

doi:10.1016/j.optcom.2011.01.035

Cited by 35 publications

(18 citation statements)

References 23 publications

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“…In recent years, research focus has shifted to thin-film, periodic nanostructures to overcome scaling and durability issues encountered in traditional color filtration. [1][2][3][4][5][6][7][8] For example, perforated metal films [1][2][3][4]7,8 and metal-insulator-metal (MIM) structures 5,6 are both capable of filtering a specific spectral band based on the surface plasmon resonance effect. Moreover, perforated metal films that are based on waveguide modes rather than surface plasmons also exhibit spectral filtering effects.…”

mentioning

confidence: 99%

High efficiency resonance-based spectrum filters with tunable transmission bandwidth fabricated using nanoimprint lithography

Kaplan

Guo

2011

Applied Physics Letters

192

146

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confidence: 99%

High efficiency resonance-based spectrum filters with tunable transmission bandwidth fabricated using nanoimprint lithography

Kaplan

Guo

2011

Applied Physics Letters

192

146

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“…Note that the use of K damped oscillators in (1) ensures the most accurate fit with the real dielectric function of Au or Ag over the infrared range considered in the present study. According to [23]- [25], the dispersion formula of the Zinc Sulfide -ZnS dielectric material has the form: …”

Section: Dgs Structure and Numerical Optimization Proceduresmentioning

confidence: 99%

Optimized Double-Layered Grating Structures for Chem/Biosensing in Midinfrared Range

Phan

Nguyen-Huu

2014

IEEE Sensors J.

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Doubled-layered grating structures (DGSs) fabricated of gold (Au) and silver (Ag), respectively, are proposed for chem/biosensing in the mid-infrared range. The geometry parameters of the DGS sensors are optimized using a rigorous coupled wave analysis (RCWA) method such that the minimum reflectance is obtained at an infrared wavelength of 4.8 µ µ µ µm or 6.7 µ µ µ µm. The magnetic field patterns and Poynting vector distributions within the optimized grating structures are examined using a finite difference time-domain (FDTD) method. The simulation results show that for a resonant wavelength of 4.8 µ µ µ µm, the Au and Ag sensors both have a sensitivity of 2000 nm/RIU (refractive index unit) and 3000 nm/RIU theoretical sensing resolution of 5x10 -6 RIU and of 1x10 -7 RIU, respectively. Similarly, for a resonant wavelength of 6.7 µ µ µ µm, the two sensors have a sensitivity of around 200 nm/RIU and theoretical resolution of 5x10 -5 RIU. In other words, the sensitivity of the DGS sensors optimized for an infrared wavelength of 4.8 µ µ µ µm is one order higher than that of the sensors optimized for a wavelength of 6.7 µ µ µ µm. In general, the results presented in this study show that the proposed DGS sensors provide a simple and versatile solution for performing chem/biosensing at midinfrared wavelengths.Index Terms-Doubled-layer gratings structure, mid-infrared wavelength, surface plasmon polaritons, cavity resonance, 1530-437X (c)

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“…Understanding the coupling of waves by metallic nanostructures has fundamental interest and practical importance in designing optical devices that could become important elements for future nano-optical systems. The primary application of such resonant periodic structures are: filters based on a dielectric layer sandwiched between two metal-dielectric gratings [23]; resonant waveguide-metallic subwavelength grating [24]; subwavelength compound metallic grating deposited on the waveguide structure [25]; nano-deep corrugated long-period waveguide gratings [26] etc.…”

Section: Introductionmentioning

confidence: 99%

Enhanced optical transmission of the triple-layer resonant waveguide structure

Yaremchuk¹

2016

Semicond. Phys. Quantum Electron. Optoelectron.

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Abstract. In this paper, we propose and demonstrate a novel guided-mode resonant filter based on a metallic grating sandwiched between two dielectric layers for TE polarization. A theoretical model based on rigorous coupled wave analysis has been developed. The transmission spectra of the grating-based structure show a high transmission band with the corresponding amplitude up to 70% inside the infra-red region. Moreover, the observed optical properties can be exactly tuned by the structural parameters. These properties allow using such structures as compact optical filters, and their spectral characteristics can be easily tuned and scaled.

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Color filters featuring high transmission efficiency and broad bandwidth based on resonant waveguide-metallic grating

Cited by 35 publications

References 23 publications

High efficiency resonance-based spectrum filters with tunable transmission bandwidth fabricated using nanoimprint lithography

High efficiency resonance-based spectrum filters with tunable transmission bandwidth fabricated using nanoimprint lithography

Optimized Double-Layered Grating Structures for Chem/Biosensing in Midinfrared Range

Enhanced optical transmission of the triple-layer resonant waveguide structure

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