Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration

Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration

Abstract Multi-junction (MJ) solar cells are one of the most promising technologies achieving high sunlight to electricity conversion efficiency. Resistive losses constitute one of the main underlying mechanisms limiting their efficiency under high illumination. In this paper, we study, by numerical...

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Main Authors: Joya Zeitouny, Eugene A. Katz, Alain Dollet, Alexis Vossier
Format: Article
Language:English
Published: Nature Publishing Group 2017-05-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-017-01854-6
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spelling doaj-b2c76355ba354102b148ecbe6dac0a2d2020-12-08T01:32:28ZengNature Publishing GroupScientific Reports2045-23222017-05-01711910.1038/s41598-017-01854-6Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar ConcentrationJoya Zeitouny0Eugene A. Katz1Alain Dollet2Alexis Vossier3CNRS-PROMESDepartment of Solar Energy and Environmental Physics, Jacob Blaustein Institutes for Desert Research, Ben-Gurion University of the NegevCNRS-PROMESCNRS-PROMESAbstract Multi-junction (MJ) solar cells are one of the most promising technologies achieving high sunlight to electricity conversion efficiency. Resistive losses constitute one of the main underlying mechanisms limiting their efficiency under high illumination. In this paper, we study, by numerical modeling, the extent to which a fine-tuning of the different electronic gaps involved in MJ stacks may mitigate the detrimental effects of series resistance losses for concentration-dependent and independent series resistances. Our results demonstrate that appropriate bandgap engineering may lead to significantly higher conversion efficiency at illumination levels above ~1000 suns and series resistance values typically exceeding 0.02 Ω cm2, due to lower operating current and, in turn, series resistance losses. The implications for future generations of solar cells aiming at an improved conversion of the solar spectrum are also addressed.https://doi.org/10.1038/s41598-017-01854-6
collection DOAJ
language English
format Article
sources DOAJ
author Joya Zeitouny
Eugene A. Katz
Alain Dollet
Alexis Vossier
spellingShingle Joya Zeitouny
Eugene A. Katz
Alain Dollet
Alexis Vossier
Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration
Scientific Reports
author_facet Joya Zeitouny
Eugene A. Katz
Alain Dollet
Alexis Vossier
author_sort Joya Zeitouny
title Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration
title_short Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration
title_full Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration
title_fullStr Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration
title_full_unstemmed Band Gap Engineering of Multi-Junction Solar Cells: Effects of Series Resistances and Solar Concentration
title_sort band gap engineering of multi-junction solar cells: effects of series resistances and solar concentration
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2017-05-01
description Abstract Multi-junction (MJ) solar cells are one of the most promising technologies achieving high sunlight to electricity conversion efficiency. Resistive losses constitute one of the main underlying mechanisms limiting their efficiency under high illumination. In this paper, we study, by numerical modeling, the extent to which a fine-tuning of the different electronic gaps involved in MJ stacks may mitigate the detrimental effects of series resistance losses for concentration-dependent and independent series resistances. Our results demonstrate that appropriate bandgap engineering may lead to significantly higher conversion efficiency at illumination levels above ~1000 suns and series resistance values typically exceeding 0.02 Ω cm2, due to lower operating current and, in turn, series resistance losses. The implications for future generations of solar cells aiming at an improved conversion of the solar spectrum are also addressed.
url https://doi.org/10.1038/s41598-017-01854-6
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AT eugeneakatz bandgapengineeringofmultijunctionsolarcellseffectsofseriesresistancesandsolarconcentration
AT alaindollet bandgapengineeringofmultijunctionsolarcellseffectsofseriesresistancesandsolarconcentration
AT alexisvossier bandgapengineeringofmultijunctionsolarcellseffectsofseriesresistancesandsolarconcentration
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