Elucidating the localized plasmonic enhancement effects from a single Ag nanowire in organic solar cells

Xinfeng Liu; Bo Wu; Qing Zhang; Jing Ngei Yip; Guannan Yu; Qihua Xiong; Nripan Mathews; Tze Chien Sum

doi:10.1021/nn505020e

Elucidating the localized plasmonic enhancement effects from a single Ag nanowire in organic solar cells

Xinfeng Liu, Bo Wu, Qing Zhang, Jing Ngei Yip, Guannan Yu, Qihua Xiong, Nripan Mathews^*, Tze Chien Sum

^*Corresponding author for this work

Nanyang Technological University

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

36 Citations (Scopus)

Abstract

The origins of performance enhancement in hybrid plasmonic organic photovoltaic devices are often embroiled in a complex interaction of light scattering, localized surface plasmon resonances, exciton-plasmon energy transfer and even nonplasmonic effects. To clearly deconvolve the plasmonic contributions from a single nanostructure, we herein investigate the influence of a single silver nanowire (NW) on the charge carriers in bulk heterojunction polymer solar cells using spatially resolved optical spectroscopy, and correlate to electrical device characterization. Polarization-dependent photocurrent enhancements with a maximum of ∼36% over the reference are observed when the transverse mode of the plasmonic excitations in the Ag NW is activated. The ensuing higher absorbance and light scattering induced by the electronic motion perpendicular to the NW long axis lead to increased exciton and polaron densities instead of direct surface plasmon-exciton energy transfer. Finite-difference time-domain simulations also validate these findings. Importantly, our study at the single nanostructure level explores the fundamental limits of plasmonic enhancement achievable in organic solar cells with a single plasmonic nanostructure.

Original language	English
Pages (from-to)	10101-10110
Number of pages	10
Journal	ACS Nano
Volume	8
Issue number	10
DOIs	https://doi.org/10.1021/nn505020e
Publication status	Published - Oct 28 2014
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2014 American Chemical Society.

ASJC Scopus Subject Areas

General Materials Science
General Engineering
General Physics and Astronomy

Keywords

organic solar cells
performance improvement
plasmonic
silver nanowire
single nanostructure
spatially resolved spectroscopy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1021/nn505020e

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abstract = "The origins of performance enhancement in hybrid plasmonic organic photovoltaic devices are often embroiled in a complex interaction of light scattering, localized surface plasmon resonances, exciton-plasmon energy transfer and even nonplasmonic effects. To clearly deconvolve the plasmonic contributions from a single nanostructure, we herein investigate the influence of a single silver nanowire (NW) on the charge carriers in bulk heterojunction polymer solar cells using spatially resolved optical spectroscopy, and correlate to electrical device characterization. Polarization-dependent photocurrent enhancements with a maximum of ∼36% over the reference are observed when the transverse mode of the plasmonic excitations in the Ag NW is activated. The ensuing higher absorbance and light scattering induced by the electronic motion perpendicular to the NW long axis lead to increased exciton and polaron densities instead of direct surface plasmon-exciton energy transfer. Finite-difference time-domain simulations also validate these findings. Importantly, our study at the single nanostructure level explores the fundamental limits of plasmonic enhancement achievable in organic solar cells with a single plasmonic nanostructure.",

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author = "Xinfeng Liu and Bo Wu and Qing Zhang and Yip, {Jing Ngei} and Guannan Yu and Qihua Xiong and Nripan Mathews and Sum, {Tze Chien}",

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AU - Liu, Xinfeng

AU - Wu, Bo

AU - Zhang, Qing

AU - Yip, Jing Ngei

AU - Yu, Guannan

AU - Xiong, Qihua

AU - Mathews, Nripan

AU - Sum, Tze Chien

PY - 2014/10/28

Y1 - 2014/10/28

N2 - The origins of performance enhancement in hybrid plasmonic organic photovoltaic devices are often embroiled in a complex interaction of light scattering, localized surface plasmon resonances, exciton-plasmon energy transfer and even nonplasmonic effects. To clearly deconvolve the plasmonic contributions from a single nanostructure, we herein investigate the influence of a single silver nanowire (NW) on the charge carriers in bulk heterojunction polymer solar cells using spatially resolved optical spectroscopy, and correlate to electrical device characterization. Polarization-dependent photocurrent enhancements with a maximum of ∼36% over the reference are observed when the transverse mode of the plasmonic excitations in the Ag NW is activated. The ensuing higher absorbance and light scattering induced by the electronic motion perpendicular to the NW long axis lead to increased exciton and polaron densities instead of direct surface plasmon-exciton energy transfer. Finite-difference time-domain simulations also validate these findings. Importantly, our study at the single nanostructure level explores the fundamental limits of plasmonic enhancement achievable in organic solar cells with a single plasmonic nanostructure.

AB - The origins of performance enhancement in hybrid plasmonic organic photovoltaic devices are often embroiled in a complex interaction of light scattering, localized surface plasmon resonances, exciton-plasmon energy transfer and even nonplasmonic effects. To clearly deconvolve the plasmonic contributions from a single nanostructure, we herein investigate the influence of a single silver nanowire (NW) on the charge carriers in bulk heterojunction polymer solar cells using spatially resolved optical spectroscopy, and correlate to electrical device characterization. Polarization-dependent photocurrent enhancements with a maximum of ∼36% over the reference are observed when the transverse mode of the plasmonic excitations in the Ag NW is activated. The ensuing higher absorbance and light scattering induced by the electronic motion perpendicular to the NW long axis lead to increased exciton and polaron densities instead of direct surface plasmon-exciton energy transfer. Finite-difference time-domain simulations also validate these findings. Importantly, our study at the single nanostructure level explores the fundamental limits of plasmonic enhancement achievable in organic solar cells with a single plasmonic nanostructure.

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Elucidating the localized plasmonic enhancement effects from a single Ag nanowire in organic solar cells

Abstract

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ASJC Scopus Subject Areas

Keywords

UN SDGs

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