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All Printable Perovskite Solar Modules with 198 cm2 Active Area and Over 6% Efficiency

Francesca De Rossi Orcid Logo, Jenny Baker Orcid Logo, David Beynon Orcid Logo, Katherine E. A. Hooper, Simone Meroni Orcid Logo, Daniel Williams, Zhengfei Wei, Amrita Yasin, Cecile Charbonneau Orcid Logo, Eifion Jewell Orcid Logo, Trystan Watson Orcid Logo

Advanced Materials Technologies, Volume: 3, Issue: 11

Swansea University Authors: Francesca De Rossi Orcid Logo, Jenny Baker Orcid Logo, David Beynon Orcid Logo, Simone Meroni Orcid Logo, Zhengfei Wei, Cecile Charbonneau Orcid Logo, Eifion Jewell Orcid Logo, Trystan Watson Orcid Logo

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DOI (Published version): 10.1002/admt.201800156

Abstract

Perovskite solar cells based on an all printable mesoporous stack, made of overlapping titania, zirconia, and carbon layers, represent a promising device architecture for both simple, low‐cost manufacture, and outstanding stability. Here a breakthrough in the upscaling of this technology is reported...

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Published in: Advanced Materials Technologies
ISSN: 2365-709X
Published: 2018
Online Access: Check full text

URI: https://cronfa.swan.ac.uk/Record/cronfa40885
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Abstract: Perovskite solar cells based on an all printable mesoporous stack, made of overlapping titania, zirconia, and carbon layers, represent a promising device architecture for both simple, low‐cost manufacture, and outstanding stability. Here a breakthrough in the upscaling of this technology is reported: Screen printed modules on A4 sized conductive glass substrates, delivering power conversion efficiency (PCE) ranging from 3 to 5% at 1 sun on an unprecedented 198 cm2 active area. An increase in the PCE, due to higher VOC and fill factor, is demonstrated by patterning the TiO2 blocking layer. Furthermore, an unexpected increase of the performance is observed over time, while storing the modules in the dark, unencapsulated, at ambient conditions (with humidity increasing from 30 and 70% RH), resulting in 6.6% PCE and 6.3% stabilised at Vmax measured after over two months since fabrication. Equally impressive is the low light performance with 11 and 18% PCE achieved respectively at 200 and 1000 lux under fluorescent lighting. It is hoped that this demonstration of good performance on large area can unlock the viability of perovskite solar cells manufactured on an industrial scale.
College: Faculty of Science and Engineering
Issue: 11

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