Hua Shen scite author profile

The influence of silver nanoparticles on light absorption in organic solar cells based on poly(3-exylthiophene):(6,6)-phenyl-C61-butyric-acid-methyl ester is studied by means of finite element method simulations. The metallic nanoparticles are embedded directly inside the active layer. We investigate the enhancement mechanism and the influence of factors such as the spacing between neighboring nanoparticles, the particle diameter, and the coating thickness. The plasmonic resonance of the particles has a wideband influence on the absorption, and we observe a rich interaction between plasmonic enhancement and the absorption characteristics of the active layer material. An enhancement with a factor of around 1.56 is observed for nanoparticles with a diameter of 24 nm and a spacing of 40 nm, bringing the structure to the absorption level of much thicker active layers without nanoparticles. In addition, a significant effect of the particle coating thickness is observed.

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Efficient Privacy-Preserving Cube-Data Aggregation Scheme for Smart Grids

Shen

Zhang

Shen

2017

IEEE Trans.Inform.Forensic Secur.

125

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Angle insensitive enhancement of organic solar cells using metallic gratings

Abass

Shen

Bienstman

et al. 2011

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We explore the optical enhancement of organic photovoltaic cells by incorporating a metallic grating as the back contact. We numerically demonstrate a strongly enhanced light absorption exploiting a complex interplay between multiple electromagnetic wave phenomena, among which Surface Plasmon Polariton (SPP) resonances, waveguide mode resonances, Fabry-Perot modes and scattering. We focus on a triangular grating structure and describe the particular opportunities to obtain a good angular performance. In addition we introduce a novel multiperiodic geometry that incorporates multiple types of SPP resonances. Our triangular structure shows an increased absorption of 15.6% with the AM1.5G spectrum in the 300-800nm wavelength range. For the multiperiodic grating case a significant further increase to 20.7% is shown. * Electronic address: aimi.abass@elis.ugent.be 1

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Blockchain-based fair payment smart contract for public cloud storage auditing

Wang

Qin

Zhao

et al. 2020

Information Sciences

137

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Combined plasmonic gratings in organic solar cells

Shen

Maes

2011

Opt. Express

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Abstract:We propose an organic solar cell structure with combined silver gratings consisting of both a front and a back grating. This combination provides multiple, semi-independent enhancement mechanisms which act additively, so that a broadband absorption is obtained. Both gratings couple the incident light into various plasmonic modes, showing a more localized or propagating character respectively. In addition, some modes only appear for tilted incident light, and therefore present a complex angle-dependent behavior. We provide extensive numerical simulations, resulting in an optimized period of 490nm, with front grating elements of 60 by 10nm and back elements of 60 by 30nm. With these parameters an integrated absorption enhancement factor around 1.35 is observed, with absorption increasing from 48% to 65% under TM polarized light. In addition, the solar cell with combined gratings is much less sensitive to the angle of incident light than the single grating cases. Furthermore, the grating structure does not have a large influence on the TE polarized light absorption.

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Hua Shen

Plasmonic absorption enhancement in organic solar cells with thin active layers

Efficient Privacy-Preserving Cube-Data Aggregation Scheme for Smart Grids

Angle insensitive enhancement of organic solar cells using metallic gratings

Blockchain-based fair payment smart contract for public cloud storage auditing

Combined plasmonic gratings in organic solar cells

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