1. Low-temperature strain-free encapsulation for perovskite solar cells and modules passing multifaceted accelerated ageing tests.
- Author
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Mariani, Paolo, Molina-García, Miguel Ángel, Barichello, Jessica, Zappia, Marilena Isabella, Magliano, Erica, Castriotta, Luigi Angelo, Gabatel, Luca, Thorat, Sanjay Balkrishna, Del Rio Castillo, Antonio Esaú, Drago, Filippo, Leonardi, Enrico, Pescetelli, Sara, Vesce, Luigi, Di Giacomo, Francesco, Matteocci, Fabio, Agresti, Antonio, De Giorgi, Nicole, Bellani, Sebastiano, Di Carlo, Aldo, and Bonaccorso, Francesco
- Subjects
SOLAR cells ,ACCELERATED life testing ,PEROVSKITE ,BUILDING-integrated photovoltaic systems ,MANUFACTURING processes ,INTERFACIAL stresses ,ADHESIVES ,BORON nitride - Abstract
Perovskite solar cells promise to be part of the future portfolio of photovoltaic technologies, but their instability is slow down their commercialization. Major stability assessments have been recently achieved but reliable accelerated ageing tests on beyond small-area cells are still poor. Here, we report an industrial encapsulation process based on the lamination of highly viscoelastic semi-solid/highly viscous liquid adhesive atop the perovskite solar cells and modules. Our encapsulant reduces the thermomechanical stresses at the encapsulant/rear electrode interface. The addition of thermally conductive two-dimensional hexagonal boron nitride into the polymeric matrix improves the barrier and thermal management properties of the encapsulant. Without any edge sealant, encapsulated devices withstood multifaceted accelerated ageing tests, retaining >80% of their initial efficiency. Our encapsulation is applicable to the most established cell configurations (direct/inverted, mesoscopic/planar), even with temperature-sensitive materials, and extended to semi-transparent cells for building-integrated photovoltaics and Internet of Things systems. The instability of perovskite solar cells hinders their commercialization. Here, authors report an industrially compatible strain-free encapsulation process based on lamination of highly viscoelastic semi-solid/highly viscous liquid encapsulant adhesive to reduce thermomechanical interfacial stress. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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