Photon absorption and photocurrent in solar cells below semiconductor bandgap due to electron photoemission from plasmonic nanoantennas

Andrey Novitsky; Alexander Uskov; Claudia Gritti; I. E. Protsenko; Beata Kardynal; Andrei Lavrinenko

doi:10.1002/pip.2278

Photon absorption and photocurrent in solar cells below semiconductor bandgap due to electron photoemission from plasmonic nanoantennas

Andrey Novitsky
, Alexander Uskov
, Claudia Gritti
, I. E. Protsenko
, Beata Kardynal
, Andrei Lavrinenko

P. N. Lebedev Physical Institute

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

We model the electron photoemission frommetal nanoparticles into a semiconductor in a Schottky diode with a conductive oxide electrode hosting the nanoparticles. We show that plasmonic effects in the nanoparticles lead to a substantial enhancement in photoemission compared with devices with continuous metal films. Optimally designed metal nanoparticles can provide an effectivemechanismfor the photon absorption in the infrared range below the semiconductor bandgap, resulting in the generation of a photocurrent in addition to the photocurrent from band-to-band absorption in a semiconductor. Such structure can form the dais of the development of plasmonic photoemission enhanced solar cells.

Original language	English
Journal	Progress in Photovoltaics
Volume	22
Issue number	4
Pages (from-to)	422-426
Number of pages	5
ISSN	1062-7995
DOIs	https://doi.org/10.1002/pip.2278
Publication status	Published - 2014

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Novitsky Progress in PhotovoltaicsAccepted author manuscript, 615 KB

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title = "Photon absorption and photocurrent in solar cells below semiconductor bandgap due to electron photoemission from plasmonic nanoantennas",

abstract = "We model the electron photoemission frommetal nanoparticles into a semiconductor in a Schottky diode with a conductive oxide electrode hosting the nanoparticles. We show that plasmonic effects in the nanoparticles lead to a substantial enhancement in photoemission compared with devices with continuous metal films. Optimally designed metal nanoparticles can provide an effectivemechanismfor the photon absorption in the infrared range below the semiconductor bandgap, resulting in the generation of a photocurrent in addition to the photocurrent from band-to-band absorption in a semiconductor. Such structure can form the dais of the development of plasmonic photoemission enhanced solar cells.",

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T1 - Photon absorption and photocurrent in solar cells below semiconductor bandgap due to electron photoemission from plasmonic nanoantennas

AU - Novitsky, Andrey

AU - Uskov, Alexander

AU - Gritti, Claudia

AU - Protsenko, I. E.

AU - Kardynal, Beata

AU - Lavrinenko, Andrei

PY - 2014

Y1 - 2014

N2 - We model the electron photoemission frommetal nanoparticles into a semiconductor in a Schottky diode with a conductive oxide electrode hosting the nanoparticles. We show that plasmonic effects in the nanoparticles lead to a substantial enhancement in photoemission compared with devices with continuous metal films. Optimally designed metal nanoparticles can provide an effectivemechanismfor the photon absorption in the infrared range below the semiconductor bandgap, resulting in the generation of a photocurrent in addition to the photocurrent from band-to-band absorption in a semiconductor. Such structure can form the dais of the development of plasmonic photoemission enhanced solar cells.

AB - We model the electron photoemission frommetal nanoparticles into a semiconductor in a Schottky diode with a conductive oxide electrode hosting the nanoparticles. We show that plasmonic effects in the nanoparticles lead to a substantial enhancement in photoemission compared with devices with continuous metal films. Optimally designed metal nanoparticles can provide an effectivemechanismfor the photon absorption in the infrared range below the semiconductor bandgap, resulting in the generation of a photocurrent in addition to the photocurrent from band-to-band absorption in a semiconductor. Such structure can form the dais of the development of plasmonic photoemission enhanced solar cells.

U2 - 10.1002/pip.2278

DO - 10.1002/pip.2278

M3 - Journal article

SN - 1062-7995

VL - 22

SP - 422

EP - 426

JO - Progress in Photovoltaics

JF - Progress in Photovoltaics

IS - 4

ER -

Photon absorption and photocurrent in solar cells below semiconductor bandgap due to electron photoemission from plasmonic nanoantennas

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