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Autori principali: Ma, Jiaming, Sabzehparvar, Milad, Pan, Ziyan, Tagliabue, Giulia
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2408.00266
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author Ma, Jiaming
Sabzehparvar, Milad
Pan, Ziyan
Tagliabue, Giulia
author_facet Ma, Jiaming
Sabzehparvar, Milad
Pan, Ziyan
Tagliabue, Giulia
contents Solar redox flow batteries (SRFB) have received much attention as an alternative integrated technology for simultaneous conversion and storage of solar energy. Yet, the photocatalytic efficiency of semiconductor-based single photoelectrode, such as hematite, remains low due to the trade-off between fast electron hole recombination and insufficient light utilization, as well as inferior reaction kinetics at the solid/liquid interface. Herein, we present an α-Fe2O3/CuxO p-n junction, coupled with a readily scalable nanostructure, that increases the electrochemically active sites and improves charge separation. Thanks to light-assisted scanning electrochemical microscopy (Photo-SECM), we elucidate the morphology-dependent carrier transfer process involved in the photo-oxidation reaction at a α-Fe2O3 photoanode. The optimized nanostructured is then exploited in the α-Fe2O3/CuxO p-n junction, achieving an outstanding unbiased photocurrent density of 0.46 mA/cm2, solar-to-chemical (STC) efficiency over 0.35% and a stable photocharge-discharge cycling. The average solar-to-output energy efficiency (SOEE) for this unassisted α-Fe2O3-based SRFB system reaches 0.18%, comparable to previously reported DSSC-assisted hematite SRFBs. The use of earth-abundant materials and the compatibility with scalable nanostructuring and heterojunction preparation techniques, offer promising opportunities for cost-effective device deployment in real-world applications.
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publishDate 2024
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spellingShingle Nanostructured Fe2O3/CuxO Heterojunction for Enhanced Solar Redox Flow Battery Performance
Ma, Jiaming
Sabzehparvar, Milad
Pan, Ziyan
Tagliabue, Giulia
Chemical Physics
Solar redox flow batteries (SRFB) have received much attention as an alternative integrated technology for simultaneous conversion and storage of solar energy. Yet, the photocatalytic efficiency of semiconductor-based single photoelectrode, such as hematite, remains low due to the trade-off between fast electron hole recombination and insufficient light utilization, as well as inferior reaction kinetics at the solid/liquid interface. Herein, we present an α-Fe2O3/CuxO p-n junction, coupled with a readily scalable nanostructure, that increases the electrochemically active sites and improves charge separation. Thanks to light-assisted scanning electrochemical microscopy (Photo-SECM), we elucidate the morphology-dependent carrier transfer process involved in the photo-oxidation reaction at a α-Fe2O3 photoanode. The optimized nanostructured is then exploited in the α-Fe2O3/CuxO p-n junction, achieving an outstanding unbiased photocurrent density of 0.46 mA/cm2, solar-to-chemical (STC) efficiency over 0.35% and a stable photocharge-discharge cycling. The average solar-to-output energy efficiency (SOEE) for this unassisted α-Fe2O3-based SRFB system reaches 0.18%, comparable to previously reported DSSC-assisted hematite SRFBs. The use of earth-abundant materials and the compatibility with scalable nanostructuring and heterojunction preparation techniques, offer promising opportunities for cost-effective device deployment in real-world applications.
title Nanostructured Fe2O3/CuxO Heterojunction for Enhanced Solar Redox Flow Battery Performance
topic Chemical Physics
url https://arxiv.org/abs/2408.00266