Quantifying the performance gain of 100 cm2bifacial four terminal perovskite-Si tandem modules

Petra Manshanden; Gianluca Coletti; Victor Rosca; Mark J. Jansen; Koen de Groot; Gertjan J. de Graaff; M. Creatore; Lukas Simurka; Mehrdad Najafi; Valerio Zardetto; Ilkar Dogan; Henri Fledderus; Sjoerd C. Veenstra

doi:10.1051/epjpv/2022006

Quantifying the performance gain of 100 cm²bifacial four terminal perovskite-Si tandem modules

Petra Manshanden (Corresponding author), Gianluca Coletti, Victor Rosca, Mark J. Jansen, Koen de Groot, Gertjan J. de Graaff, M. Creatore, Lukas Simurka, Mehrdad Najafi, Valerio Zardetto, Ilkar Dogan, Henri Fledderus, Sjoerd C. Veenstra

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Abstract

Improving the performance of solar modules requires the implementation of both spectral and directional irradiance optimization. The performance of bifacial four-terminal tandem minimodules with a 100 cm2 area is reported, both indoor and outdoor measurements. We demonstrate a 24.5 mW/cm2 (bifacial irradiance 200 W/m2) bifacial tandem power density, measured according to a tandem adapted IEC60904-1-2 protocol, which constitutes a 3 mW/cm2 gain with respect to monofacial use. In addition, we show that in outdoor measurements bifacial four terminal tandems outperform identical monofacial four terminal tandems by 26% on average, depending on incident angle, injection level and temperature, in a 10% albedo environment. The average gain is higher for outdoor performance than for indoor performance, due to variations in relative rear irradiance.

Original language	English
Article number	11
Number of pages	8
Journal	EPJ Photovoltaics
Volume	13
DOIs	https://doi.org/10.1051/epjpv/2022006
Publication status	Published - 2022

Keywords

Bifacial modules
Four terminal tandem
Outdoor performance
Perovskite

UN SDGs

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

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10.1051/epjpv/2022006

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Cite this

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title = "Quantifying the performance gain of 100 cm2bifacial four terminal perovskite-Si tandem modules",

abstract = "Improving the performance of solar modules requires the implementation of both spectral and directional irradiance optimization. The performance of bifacial four-terminal tandem minimodules with a 100 cm2 area is reported, both indoor and outdoor measurements. We demonstrate a 24.5 mW/cm2 (bifacial irradiance 200 W/m2) bifacial tandem power density, measured according to a tandem adapted IEC60904-1-2 protocol, which constitutes a 3 mW/cm2 gain with respect to monofacial use. In addition, we show that in outdoor measurements bifacial four terminal tandems outperform identical monofacial four terminal tandems by 26% on average, depending on incident angle, injection level and temperature, in a 10% albedo environment. The average gain is higher for outdoor performance than for indoor performance, due to variations in relative rear irradiance.",

keywords = "Bifacial modules, Four terminal tandem, Outdoor performance, Perovskite",

author = "Petra Manshanden and Gianluca Coletti and Victor Rosca and Jansen, {Mark J.} and {de Groot}, Koen and {de Graaff}, {Gertjan J.} and M. Creatore and Lukas Simurka and Mehrdad Najafi and Valerio Zardetto and Ilkar Dogan and Henri Fledderus and Veenstra, {Sjoerd C.}",

year = "2022",

doi = "10.1051/epjpv/2022006",

language = "English",

volume = "13",

journal = "EPJ Photovoltaics",

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T1 - Quantifying the performance gain of 100 cm2bifacial four terminal perovskite-Si tandem modules

AU - Manshanden, Petra

AU - Coletti, Gianluca

AU - Rosca, Victor

AU - Jansen, Mark J.

AU - de Groot, Koen

AU - de Graaff, Gertjan J.

AU - Creatore, M.

AU - Simurka, Lukas

AU - Najafi, Mehrdad

AU - Zardetto, Valerio

AU - Dogan, Ilkar

AU - Fledderus, Henri

AU - Veenstra, Sjoerd C.

PY - 2022

Y1 - 2022

N2 - Improving the performance of solar modules requires the implementation of both spectral and directional irradiance optimization. The performance of bifacial four-terminal tandem minimodules with a 100 cm2 area is reported, both indoor and outdoor measurements. We demonstrate a 24.5 mW/cm2 (bifacial irradiance 200 W/m2) bifacial tandem power density, measured according to a tandem adapted IEC60904-1-2 protocol, which constitutes a 3 mW/cm2 gain with respect to monofacial use. In addition, we show that in outdoor measurements bifacial four terminal tandems outperform identical monofacial four terminal tandems by 26% on average, depending on incident angle, injection level and temperature, in a 10% albedo environment. The average gain is higher for outdoor performance than for indoor performance, due to variations in relative rear irradiance.

AB - Improving the performance of solar modules requires the implementation of both spectral and directional irradiance optimization. The performance of bifacial four-terminal tandem minimodules with a 100 cm2 area is reported, both indoor and outdoor measurements. We demonstrate a 24.5 mW/cm2 (bifacial irradiance 200 W/m2) bifacial tandem power density, measured according to a tandem adapted IEC60904-1-2 protocol, which constitutes a 3 mW/cm2 gain with respect to monofacial use. In addition, we show that in outdoor measurements bifacial four terminal tandems outperform identical monofacial four terminal tandems by 26% on average, depending on incident angle, injection level and temperature, in a 10% albedo environment. The average gain is higher for outdoor performance than for indoor performance, due to variations in relative rear irradiance.

KW - Bifacial modules

KW - Four terminal tandem

KW - Outdoor performance

KW - Perovskite

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