Enabling bifacial thin film devices by developing a back surface field using CuxAlOy

Enabling bifacial thin film devices by developing a back surface field using CuxAlOy

Bifacial solar cells have the potential to increase the energy yield per unit area over traditional monofacial devices without significant added cost, driving $/kWh costs lower and accelerating the adoption of solar photovoltaics. However, the performance of bifacial thin film solar cells significan...

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Bibliographic Details
Published in:Nano energy Vol. 83; no. C
Main Authors: Subedi, Kamala Khanal, Phillips, Adam B., Shrestha, Niraj, Alfadhili, Fadhil K., Osella, Anna, Subedi, Indra, Awni, Rasha A., Bastola, Ebin, Song, Zhaoning, Li, Deng-Bing, Collins, Robert W., Yan, Yanfa, Podraza, Nikolas J., Heben, Michael J., Ellingson, Randy J.
Format: Journal Article
Language:English
Published: United States Elsevier 01-05-2021
Subjects:
bifacial
CdTe
Chemistry
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
CuxAlOy
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
MATERIALS SCIENCE
Physics
positive IFLO
Science & Technology - Other Topics
thin films
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Summary:Bifacial solar cells have the potential to increase the energy yield per unit area over traditional monofacial devices without significant added cost, driving $/kWh costs lower and accelerating the adoption of solar photovoltaics. However, the performance of bifacial thin film solar cells significantly lags that achieved by crystalline silicon cells. Here we incorporate wide bandgap CuxAlOy as a back buffer layer for CdTe devices and achieve a backside illuminated device with high current density and high fill factor. Moreover, these values remain nearly constant even as the absorber layer thickness changes, indicating that a fully-depleted device is not required for efficient charge collection. We show that this response is indicative of a back surface field, albeit with a persistent high back surface recombination velocity. By managing electron reflection, we achieved a backside illumination conversion efficiency of 7.1% and bifaciality of 0.55 for a 3.3 µm CdTe device and 8.0% and 0.62 for a 2 µm device. Future improvements can be made by identifying and incorporating a passivation material that reduces the back surface recombination velocity.
Bibliography:USDOE Office of Energy Efficiency and Renewable Energy (EERE)
EE0008974; FA9453-18-2-0037; FA9453-19-C-1002
US Air Force Office of Scientific Research (AFOSR)
ISSN:2211-2855