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Main Authors: Wang, T., Ehre, F., Weiss, T. P., Veith-Wolf, B., Titova, V., Valle, N., Melchiorre, M., Schmidt, J., Siebentritt, S.
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2204.06483
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author Wang, T.
Ehre, F.
Weiss, T. P.
Veith-Wolf, B.
Titova, V.
Valle, N.
Melchiorre, M.
Schmidt, J.
Siebentritt, S.
author_facet Wang, T.
Ehre, F.
Weiss, T. P.
Veith-Wolf, B.
Titova, V.
Valle, N.
Melchiorre, M.
Schmidt, J.
Siebentritt, S.
contents Metastable defects can decisively influence the diode factor and thus the efficiency of a solar cell. The diode factor is also influenced by the doping level and the recombination mechanisms in the solar cell. Here we quantify how the various parameters change the diode factor by photoluminescence measurements and simulations. In addition, we show that backside recombination reduces the open circuit voltage in CuInSe2 solar cells by more than 40 mV. Passivation by a Ga gradient is shown to be as efficient as a passivation by dielectric layers. Increased backside recombination reduces the diode factor, not because of less metastable defect transformation but because of a sublinear increase in photo generated carriers with excitation. This reduction in diode factor is unwanted, since the increased recombination reduces the voltage. A higher doping level, on the other hand, reduces the diode factor, thereby increasing the fill factor, and at the same time increases the voltage.
format Preprint
id arxiv_https___arxiv_org_abs_2204_06483
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Solar cell efficiency, diode factor and interface recombination: insights from photoluminescence
Wang, T.
Ehre, F.
Weiss, T. P.
Veith-Wolf, B.
Titova, V.
Valle, N.
Melchiorre, M.
Schmidt, J.
Siebentritt, S.
Applied Physics
Materials Science
Metastable defects can decisively influence the diode factor and thus the efficiency of a solar cell. The diode factor is also influenced by the doping level and the recombination mechanisms in the solar cell. Here we quantify how the various parameters change the diode factor by photoluminescence measurements and simulations. In addition, we show that backside recombination reduces the open circuit voltage in CuInSe2 solar cells by more than 40 mV. Passivation by a Ga gradient is shown to be as efficient as a passivation by dielectric layers. Increased backside recombination reduces the diode factor, not because of less metastable defect transformation but because of a sublinear increase in photo generated carriers with excitation. This reduction in diode factor is unwanted, since the increased recombination reduces the voltage. A higher doping level, on the other hand, reduces the diode factor, thereby increasing the fill factor, and at the same time increases the voltage.
title Solar cell efficiency, diode factor and interface recombination: insights from photoluminescence
topic Applied Physics
Materials Science
url https://arxiv.org/abs/2204.06483