Bifacial Schottky-Junction Plasmonic-Based Solar Cell

Mohamed Farhat; Ahmer A.B. Baloch; Sergey N. Rashkeev; Nouar Tabet; Sabre Kais; Fahhad H. Alharbi

doi:10.1002/ente.201901280

Bifacial Schottky-Junction Plasmonic-Based Solar Cell

Mohamed Farhat, Ahmer A.B. Baloch, Sergey N. Rashkeev, Nouar Tabet, Sabre Kais, Fahhad H. Alharbi^*

^*Corresponding author for this work

Department of Electrical Engineering

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

2 Scopus citations

Abstract

Plasmonically-enhanced and Schottky-based devices are very appealing candidates for sunlight energy–harvesting applications. However, this class of structures introduces inherent limitations such as thermionic emission (and the related dark current). This article theoretically proposes using the metal–semiconductor–metal heterojunction under bifacial mode. In this design, plasmonic periodic gratings are introduced in the bifacial configuration to allow collection of light from both faces of the solar junction. This results in improved carrier generation and enhanced device performance of a cell with a 3 μm thick Si absorber. Bifacial gain for short circuit current is found to be 88%, with a bifaciality factor (the ratio of rear to front response of the device) of 84%. By optimizing the filling fractions of the front and rear plasmonic gratings, the obtained normalized output becomes higher than 25%; i.e., it almost doubles the performance in comparison with the monofacial Schottky solar cell.

Original language	English
Article number	1901280
Journal	Energy Technology
Volume	8
Issue number	5
DOIs	https://doi.org/10.1002/ente.201901280
State	Published - 1 May 2020

Bibliographical note

Publisher Copyright:
© 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

Keywords

Schottky junction
bifacial
optoelectronics
photovoltaics
plasmonics

ASJC Scopus subject areas

General Energy

UN SDGs

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

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10.1002/ente.201901280

Cite this

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title = "Bifacial Schottky-Junction Plasmonic-Based Solar Cell",

abstract = "Plasmonically-enhanced and Schottky-based devices are very appealing candidates for sunlight energy–harvesting applications. However, this class of structures introduces inherent limitations such as thermionic emission (and the related dark current). This article theoretically proposes using the metal–semiconductor–metal heterojunction under bifacial mode. In this design, plasmonic periodic gratings are introduced in the bifacial configuration to allow collection of light from both faces of the solar junction. This results in improved carrier generation and enhanced device performance of a cell with a 3 μm thick Si absorber. Bifacial gain for short circuit current is found to be 88\%, with a bifaciality factor (the ratio of rear to front response of the device) of 84\%. By optimizing the filling fractions of the front and rear plasmonic gratings, the obtained normalized output becomes higher than 25\%; i.e., it almost doubles the performance in comparison with the monofacial Schottky solar cell.",

keywords = "Schottky junction, bifacial, optoelectronics, photovoltaics, plasmonics",

author = "Mohamed Farhat and Baloch, \{Ahmer A.B.\} and Rashkeev, \{Sergey N.\} and Nouar Tabet and Sabre Kais and Alharbi, \{Fahhad H.\}",

note = "Publisher Copyright: {\textcopyright} 2020 WILEY-VCH Verlag GmbH \& Co. KGaA, Weinheim",

year = "2020",

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T1 - Bifacial Schottky-Junction Plasmonic-Based Solar Cell

AU - Farhat, Mohamed

AU - Baloch, Ahmer A.B.

AU - Rashkeev, Sergey N.

AU - Tabet, Nouar

AU - Kais, Sabre

AU - Alharbi, Fahhad H.

PY - 2020/5/1

Y1 - 2020/5/1

N2 - Plasmonically-enhanced and Schottky-based devices are very appealing candidates for sunlight energy–harvesting applications. However, this class of structures introduces inherent limitations such as thermionic emission (and the related dark current). This article theoretically proposes using the metal–semiconductor–metal heterojunction under bifacial mode. In this design, plasmonic periodic gratings are introduced in the bifacial configuration to allow collection of light from both faces of the solar junction. This results in improved carrier generation and enhanced device performance of a cell with a 3 μm thick Si absorber. Bifacial gain for short circuit current is found to be 88%, with a bifaciality factor (the ratio of rear to front response of the device) of 84%. By optimizing the filling fractions of the front and rear plasmonic gratings, the obtained normalized output becomes higher than 25%; i.e., it almost doubles the performance in comparison with the monofacial Schottky solar cell.

AB - Plasmonically-enhanced and Schottky-based devices are very appealing candidates for sunlight energy–harvesting applications. However, this class of structures introduces inherent limitations such as thermionic emission (and the related dark current). This article theoretically proposes using the metal–semiconductor–metal heterojunction under bifacial mode. In this design, plasmonic periodic gratings are introduced in the bifacial configuration to allow collection of light from both faces of the solar junction. This results in improved carrier generation and enhanced device performance of a cell with a 3 μm thick Si absorber. Bifacial gain for short circuit current is found to be 88%, with a bifaciality factor (the ratio of rear to front response of the device) of 84%. By optimizing the filling fractions of the front and rear plasmonic gratings, the obtained normalized output becomes higher than 25%; i.e., it almost doubles the performance in comparison with the monofacial Schottky solar cell.

KW - Schottky junction

KW - bifacial

KW - optoelectronics

KW - photovoltaics

KW - plasmonics

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SN - 2194-4288

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JO - Energy Technology

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M1 - 1901280

ER -

Bifacial Schottky-Junction Plasmonic-Based Solar Cell

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

Access to Document

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Cite this