Lumped-element model of plasmonic solar cells

Chang Hyun Kim; Maria Seitanidou; Jong Woo Jin; Yvan Bonnassieux; Gilles Horowitz; Ioannis Vangelidis; Elefterios Lidorikis; Argiris Laskarakis; Stergios Logothetidis

doi:10.1016/j.sse.2018.06.005

Lumped-element model of plasmonic solar cells

Chang Hyun Kim
, Maria Seitanidou
, Jong Woo Jin
, Yvan Bonnassieux
, Gilles Horowitz
, Ioannis Vangelidis
, Elefterios Lidorikis
, Argiris Laskarakis
, Stergios Logothetidis

Research output: Contribution to journal › Article › peer-review

Abstract

Although metallic nanostructures in solar cells provide versatility in designing useful plasmonic architectures, understanding is still limited on how to exploit their multi-scale contribution as tunable performance. In this article, we suggest a characteristic model that develops into a simple and robust tool for guiding optimization of plasmonic solar devices. The model is conceptually based on the breakdown of the active region into intrinsic and plasmonic sub-circuits, by which the terminal currents are directly correlated with particle geometries and local improvement. Measurements from organic cells support the validity of our theory, and a series of simulation provides further insights into the critical trade-off between voltage and current generation, finally offering a strategy for efficiency enhancement.

Original language	English
Pages (from-to)	39-43
Number of pages	5
Journal	Solid-State Electronics
Volume	147
DOIs	https://doi.org/10.1016/j.sse.2018.06.005
Publication status	Published - 1 Sept 2018

Keywords

Equivalent circuits
Lumped-element model
Metal nanoparticles
Plasmonics
Solar cells

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10.1016/j.sse.2018.06.005

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title = "Lumped-element model of plasmonic solar cells",

abstract = "Although metallic nanostructures in solar cells provide versatility in designing useful plasmonic architectures, understanding is still limited on how to exploit their multi-scale contribution as tunable performance. In this article, we suggest a characteristic model that develops into a simple and robust tool for guiding optimization of plasmonic solar devices. The model is conceptually based on the breakdown of the active region into intrinsic and plasmonic sub-circuits, by which the terminal currents are directly correlated with particle geometries and local improvement. Measurements from organic cells support the validity of our theory, and a series of simulation provides further insights into the critical trade-off between voltage and current generation, finally offering a strategy for efficiency enhancement.",

keywords = "Equivalent circuits, Lumped-element model, Metal nanoparticles, Plasmonics, Solar cells",

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T1 - Lumped-element model of plasmonic solar cells

AU - Kim, Chang Hyun

AU - Seitanidou, Maria

AU - Jin, Jong Woo

AU - Bonnassieux, Yvan

AU - Horowitz, Gilles

AU - Vangelidis, Ioannis

AU - Lidorikis, Elefterios

AU - Laskarakis, Argiris

AU - Logothetidis, Stergios

PY - 2018/9/1

Y1 - 2018/9/1

N2 - Although metallic nanostructures in solar cells provide versatility in designing useful plasmonic architectures, understanding is still limited on how to exploit their multi-scale contribution as tunable performance. In this article, we suggest a characteristic model that develops into a simple and robust tool for guiding optimization of plasmonic solar devices. The model is conceptually based on the breakdown of the active region into intrinsic and plasmonic sub-circuits, by which the terminal currents are directly correlated with particle geometries and local improvement. Measurements from organic cells support the validity of our theory, and a series of simulation provides further insights into the critical trade-off between voltage and current generation, finally offering a strategy for efficiency enhancement.

AB - Although metallic nanostructures in solar cells provide versatility in designing useful plasmonic architectures, understanding is still limited on how to exploit their multi-scale contribution as tunable performance. In this article, we suggest a characteristic model that develops into a simple and robust tool for guiding optimization of plasmonic solar devices. The model is conceptually based on the breakdown of the active region into intrinsic and plasmonic sub-circuits, by which the terminal currents are directly correlated with particle geometries and local improvement. Measurements from organic cells support the validity of our theory, and a series of simulation provides further insights into the critical trade-off between voltage and current generation, finally offering a strategy for efficiency enhancement.

KW - Equivalent circuits

KW - Lumped-element model

KW - Metal nanoparticles

KW - Plasmonics

KW - Solar cells

U2 - 10.1016/j.sse.2018.06.005

DO - 10.1016/j.sse.2018.06.005

M3 - Article

AN - SCOPUS:85048437296

SN - 0038-1101

VL - 147

SP - 39

EP - 43

JO - Solid-State Electronics

JF - Solid-State Electronics

ER -

Lumped-element model of plasmonic solar cells

Abstract

Keywords

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