Nanoparticle Stacks with Graded Refractive Indices Enhance the Omnidirectional Light Harvesting of Solar Cells and the Light Extraction of Light‐Emitting Diodes

Fang, Chengcheng; Liu, Yu-Lun; Lee, Yang–Chun; Chen, Hsuen‐Li; Wan, Dehui; Yu, Chung-Han

doi:10.1002/adfm.201201949

Cited by 50 publications

(28 citation statements)

References 56 publications

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“…In Figure A, the GRIN structure consists of several layers with the refractive index (n) decreasing along the normal direction. Due to the mass difference in the refractive index, the nongradient structure produces total reflection at the coating‐air interface . Therefore, the GRIN structure can reduce the difference in the refractive index.…”

Section: Introductionmentioning

confidence: 99%

Gradient refractive index structure of phosphor‐in‐glass coating for packaging of white LEDs

Zhuo

et al. 2018

J Am Ceram Soc

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A gradient refractive index (GRIN) structure, with a gradual increase in the refractive index from the glass substrate, was successfully obtained by multilayer screen printing for white light‐emitting diodes (w‐LEDs) packaging. Each phosphor‐in‐glass (PiG) coating consisted of B2O3–SiO2–ZnO glass matrix and yellow phosphor. The gradually increased refractive index (1.62, 1.72, and 1.82) of glass matrices were obtained from higher molecular weight of La2O3 and WO3. After sintering at 600°C, no obvious interface was observed and the phosphor particles were mixed thoroughly in the glass matrix. When the phosphor content was 50 wt%, the white‐light emission was obtained. Compared with those based on the nongradient and low‐refractive PiG coating, the luminous efficacy of w‐LEDs constructed by the PiG coating with GRIN was enhanced. It shows that the GRIN structure is beneficial to improve the luminous efficacy of w‐LEDs.

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Section: Introductionmentioning

confidence: 99%

Gradient refractive index structure of phosphor‐in‐glass coating for packaging of white LEDs

Zhuo

et al. 2018

J Am Ceram Soc

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“…For planar surfaces, many strategies have been developed to fabricate functional nanocoatings with well‐controlled thickness like self‐assembling, spin‐coating, dip‐coating, and chemical vapor deposition . However, preparation of conformal and thickness‐controllable nanocoatings on microstructured surfaces is more challenging.…”

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confidence: 99%

Conformal Nanocoatings with Uniform and Controllable Thickness on Microstructured Surfaces: A General Assembly Route

et al. 2018

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Assembling nanoparticles (NPs) on various surfaces are intensively investigated for the construction of functional nanocoatings; however, it is still a challenge to fabricate conformal nanocoatings uniformly on surfaces having micro- or nanostructures. Herein, it is demonstrated that the negatively charged SiO NPs and the positively charged silicon coupling agent can be assembled layer-by-layer on the microstructures based on the combination of electrostatic interaction and condensation reaction. Conformal nanocoatings with controllable thickness are formed on the microstructured surfaces with different compositions and morphologies. The formation mechanism is confirmed by using quartz crystal microbalance with dissipation (QCM-D) to study the assembly process in real time. The universality of this method is illustrated by using other reactive building blocks with opposite charge to build up the conformal nanocoatings. Application in the preparation of antireflective nanocoatings on nonplanar optical materials is demonstrated. This simple, versatile, and scalable strategy for the preparation of conformal nanocoatings is promising for practical applications.

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“…14 Coupled nanoparticles can sustain the light oscillation and allow it to travel upto several hundred nanometers without damping. 15 In this way, nanoparticles arranged in a row can form a nanosize waveguide that can be used for data transferring in a computer chip, 16,17 light trapping in plasmonic solar cell, 18,19 metamaterial research, 20,21 single photon sources, 22 and anisotropic Surface Enhanced Raman Scattering sensors. 9 For all these applications, there are two fundamental requirements: first to develop a process for making closely arranged nanoparticles arrays and second, an optical model that can calculate the dielectric coefficients to investigate the field enhancement and coupling effect.…”

Section: Introductionmentioning

confidence: 99%

Localized surface plasmon resonance anisotropy in template aligned silver nanoparticles: A case of biaxial metal optics

Ranjan

Bhatnagar

Mukherjee

2015

Journal of Applied Physics

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Generalized ellipsometry is used to extract the dielectric functions of self-aligned silver nanoparticles on silicon ripple patterns which account for the anisotropic Localized Surface Plasmon Resonance shown by such nanostructures. The biaxial nature of dielectric functions shows its presence through the modified in-plane plasmonic behaviour as compared to the case of random nanoparticles. The nature of in-plane optical coupling and out of plane metallic behavior is further investigated by tuning the interparticle gap along the ripple direction and also varying the ripple periodicity. Thus, we propose that generalized ellipsometry may be used as an effective process monitoring technique to develop anisotropic plasmonic substrates with potential applications in photovoltaic systems as a plasmonic back reflector.

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Nanoparticle Stacks with Graded Refractive Indices Enhance the Omnidirectional Light Harvesting of Solar Cells and the Light Extraction of Light‐Emitting Diodes

Cited by 50 publications

References 56 publications

Gradient refractive index structure of phosphor‐in‐glass coating for packaging of white LEDs

Gradient refractive index structure of phosphor‐in‐glass coating for packaging of white LEDs

Conformal Nanocoatings with Uniform and Controllable Thickness on Microstructured Surfaces: A General Assembly Route

Localized surface plasmon resonance anisotropy in template aligned silver nanoparticles: A case of biaxial metal optics

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