As a vital step towards the industrialization of perovskite solar cells, outdoor field tests of large-scale perovskite modules and panels represent a mandatory step to be accomplished. Here we demonstrate the manufacturing of large-area (0.5 m2) perovskite solar panels, each containing 40 modules whose interfaces are engineered with two-dimensional materials (GRAphene-PErovskite (GRAPE) panels). We further integrate nine GRAPE panels for a total panel area of 4.5 m2 in a stand-alone solar farm infrastructure with peak power exceeding 250 W, proving the scalability of this technology. We provide insights on the system operation by analysing the panel characteristics as a function of temperature and light intensity. The analysis, carried out over a months-long timescale, highlights the key role of the lamination process of the panels on the entire system degradation. A life-cycle assessment based on primary data indicates the high commercial potential of the GRAPE panel technology in terms of energy and environmental performances.

Pescetelli, S., Agresti, A., Viskadouros, G., Razza, S., Rogdakis: Ioannis Kalogerakis, K., Spiliarotis, E., et al. (2022). Integration of two-dimensional materials-based perovskite solar panels into a stand-alone solar farm. NATURE ENERGY.

Integration of two-dimensional materials-based perovskite solar panels into a stand-alone solar farm

Sara Pescetelli;Antonio Agresti;Stefano Razza;Paolo Mariani;Luca Sorbello;Cristina Cornaro;Aldo Di Carlo.
2022-01-01

Abstract

As a vital step towards the industrialization of perovskite solar cells, outdoor field tests of large-scale perovskite modules and panels represent a mandatory step to be accomplished. Here we demonstrate the manufacturing of large-area (0.5 m2) perovskite solar panels, each containing 40 modules whose interfaces are engineered with two-dimensional materials (GRAphene-PErovskite (GRAPE) panels). We further integrate nine GRAPE panels for a total panel area of 4.5 m2 in a stand-alone solar farm infrastructure with peak power exceeding 250 W, proving the scalability of this technology. We provide insights on the system operation by analysing the panel characteristics as a function of temperature and light intensity. The analysis, carried out over a months-long timescale, highlights the key role of the lamination process of the panels on the entire system degradation. A life-cycle assessment based on primary data indicates the high commercial potential of the GRAPE panel technology in terms of energy and environmental performances.
2022
Pubblicato
Rilevanza internazionale
Articolo
Esperti anonimi
Settore ING-IND/11 - FISICA TECNICA AMBIENTALE
English
Con Impact Factor ISI
Pescetelli, S., Agresti, A., Viskadouros, G., Razza, S., Rogdakis: Ioannis Kalogerakis, K., Spiliarotis, E., et al. (2022). Integration of two-dimensional materials-based perovskite solar panels into a stand-alone solar farm. NATURE ENERGY.
Pescetelli, S; Agresti, A; Viskadouros, G; Razza, S; Rogdakis: Ioannis Kalogerakis, K; Spiliarotis, E; Leonardi, E; Mariani, P; Sorbello, L; Pierro, M...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2108/303012
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