Photon upconversion assisted ferroelectric photovoltaics: Device configuration with multifaceted influence in augmenting the photovoltaic response of BiFeO3 thin‐film solar cells

This work presents a novel paradigm for upconversion‐assisted ferroelectric photovoltaic devices. The system comprises a ferroelectric active layer (BiFeO3), an upconverter layer (Yb; Er‐doped ZnO), a conductive ITO‐coated glass substrate, and a reflective coating (Al) at the rear end of the glass s...

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Veröffentlicht in:	Progress in photovoltaics 2024-08, Vol.32 (8), p.556-568
Hauptverfasser:	Wani, Waseem Ahmad, Gupta, Gaurav, Rath, Shyama, Venkataraman, Harihara, Ramaswamy, Kannan
Format:	Artikel
Sprache:	eng
Schlagworte:	Bismuth ferrite Efficiency Erbium Ferroelectric materials ferroelectric photovoltaics Ferroelectricity Glass substrates heterojunction Perovskites Photovoltaic cells Solar cells Thin films Upconversion Ytterbium Zinc oxide
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container_title	Progress in photovoltaics
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creator	Wani, Waseem Ahmad Gupta, Gaurav Rath, Shyama Venkataraman, Harihara Ramaswamy, Kannan
description	This work presents a novel paradigm for upconversion‐assisted ferroelectric photovoltaic devices. The system comprises a ferroelectric active layer (BiFeO3), an upconverter layer (Yb; Er‐doped ZnO), a conductive ITO‐coated glass substrate, and a reflective coating (Al) at the rear end of the glass substrate. The photovoltaic efficiency of the single‐layer BFO was found to be 0.71%. With the prescribed device model, the total solar efficiency of BiFeO3 improved significantly and touched solar conversion efficiency of 2.21%. This model's projection widens the future perspectives of device performance in emerging photovoltaic technology, mainly perovskite‐based solar cells. This work presents a novel paradigm for upconversion‐assisted ferroelectric photovoltaic devices. Heterojunction systems like this one have a multifaceted impact on the overall device performance and photovoltaic efficiency by a significant amount.
doi_str_mv	10.1002/pip.3793
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source	Wiley Online Library Journals Frontfile Complete
subjects	Bismuth ferrite Efficiency Erbium Ferroelectric materials ferroelectric photovoltaics Ferroelectricity Glass substrates heterojunction Perovskites Photovoltaic cells Solar cells Thin films Upconversion Ytterbium Zinc oxide
title	Photon upconversion assisted ferroelectric photovoltaics: Device configuration with multifaceted influence in augmenting the photovoltaic response of BiFeO3 thin‐film solar cells
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