Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study

The investigation dealt with the effect of Fe and Au wt.% concentrations on the enhanced performance and stability of Ni/GDC under rSOC operation. Moreover, it focused on the comparison of the intrinsic electro-kinetics between the best performing Fe–Au-modified cell and Ni/GDC under SOE operation....

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Κύριοι συγγραφείς:	Ζαραβέλης, Φώτιος, Νιάκολας, Δημήτριος
Άλλοι συγγραφείς:	Zaravelis, Fotios
Έκδοση:	International Journal of Hydrogen Energy 2023
Θέματα:	Reversible solid oxide cell operation Ni/GDC Fe–Au doping Intrinsic electro-kinetics enhancement
Διαθέσιμο Online:	https://doi.org/10.1016/j.ijhydene.2023.06.034 https://hdl.handle.net/10889/25191

id	nemertes-10889-25191
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spelling	nemertes-10889-251912023-06-27T03:52:16Z Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study Ζαραβέλης, Φώτιος Νιάκολας, Δημήτριος Zaravelis, Fotios Niakolas, Dimitrios Reversible solid oxide cell operation Ni/GDC Fe–Au doping Intrinsic electro-kinetics enhancement The investigation dealt with the effect of Fe and Au wt.% concentrations on the enhanced performance and stability of Ni/GDC under rSOC operation. Moreover, it focused on the comparison of the intrinsic electro-kinetics between the best performing Fe–Au-modified cell and Ni/GDC under SOE operation. The rSOC performance and stability of all cells was examined in the temperature range of 900–800 °C. The electro-kinetic measurements took place at 900 °C by varying the pH2O. All Fe–Au–Ni/GDC electrodes exhibited enhanced activity, compared to the SoA Ni/GDC, with variations in their stability after three rSOC cycles. Specifically, the fuel electrode with the lowest wt.% concentration in Fe and Au (0.5Fe–1Au–Ni/GDC) exhibited the highest activity and stability under rSOC operation. By increasing the wt.% loadings to 2 wt.% Fe and 3 wt.% Au, there was rapid degradation of the initially high performance, mainly due to increase of the ohmic resistance. SEM analysis showed higher macro-porosity on the reduced state of the modified electrodes, which in the case of the best performing 0.5Fe–1Au–Ni/GDC was the least affected after rSOC operation. Interestingly, the SOE performance of the examined Fe–Au-modified electrodes was not similarly inhibited by the decrease of temperature, compared to Ni/GDC. This was further clarified through electro-kinetic measurements, aiming to verify the effect from the Fe–Au doping on the intrinsic electrochemical activity of Ni/GDC for the H2O electrolysis reaction. Comparison between the SoA and the best performing 0.5Fe–1Au–Ni/GDC showed an enhancing effect on the intrinsic electro-kinetics of the modified electrode. Specifically, the dependence of the polarization resistance on the pH2O was found to be strongly positive, resulting in a higher apparent reaction order, compared to Ni/GDC. The authors would like to thank Dr. Stylianos G. Neophytides, Research Director at the Institute of Chemical Engineering Sciences (FORTH/ICEHT) for the constructive comments and Ms., Dr. Vayia Xanthopoulou, researcher at the Laboratory of Electron Microscopy and Microanalysis, School of Natural Sciences, University of Patras, for the XRF analysis. The research leading to these results has received funding from the Fuel Cells and Hydrogen 2 Joint Undertaking (now Clean Hydrogen Partnership) under the projects NewSOC [Horizon 2020], Grant Agreement No 874577 and 24_7 ZEN [Horizon Europe], Grant Agreement No 101101418. This Joint Undertaking receives support from the European Union's Horizon 2020 Research and Innovation program, Hydrogen Europe and Hydrogen Europe Research. 2023-06-26T11:08:57Z 2023-06-26T11:08:57Z 2023-06-22 https://doi.org/10.1016/j.ijhydene.2023.06.034 https://hdl.handle.net/10889/25191 application/pdf International Journal of Hydrogen Energy
institution	UPatras
collection	Nemertes
topic	Reversible solid oxide cell operation Ni/GDC Fe–Au doping Intrinsic electro-kinetics enhancement
spellingShingle	Reversible solid oxide cell operation Ni/GDC Fe–Au doping Intrinsic electro-kinetics enhancement Ζαραβέλης, Φώτιος Νιάκολας, Δημήτριος Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study
description	The investigation dealt with the effect of Fe and Au wt.% concentrations on the enhanced performance and stability of Ni/GDC under rSOC operation. Moreover, it focused on the comparison of the intrinsic electro-kinetics between the best performing Fe–Au-modified cell and Ni/GDC under SOE operation. The rSOC performance and stability of all cells was examined in the temperature range of 900–800 °C. The electro-kinetic measurements took place at 900 °C by varying the pH2O. All Fe–Au–Ni/GDC electrodes exhibited enhanced activity, compared to the SoA Ni/GDC, with variations in their stability after three rSOC cycles. Specifically, the fuel electrode with the lowest wt.% concentration in Fe and Au (0.5Fe–1Au–Ni/GDC) exhibited the highest activity and stability under rSOC operation. By increasing the wt.% loadings to 2 wt.% Fe and 3 wt.% Au, there was rapid degradation of the initially high performance, mainly due to increase of the ohmic resistance. SEM analysis showed higher macro-porosity on the reduced state of the modified electrodes, which in the case of the best performing 0.5Fe–1Au–Ni/GDC was the least affected after rSOC operation. Interestingly, the SOE performance of the examined Fe–Au-modified electrodes was not similarly inhibited by the decrease of temperature, compared to Ni/GDC. This was further clarified through electro-kinetic measurements, aiming to verify the effect from the Fe–Au doping on the intrinsic electrochemical activity of Ni/GDC for the H2O electrolysis reaction. Comparison between the SoA and the best performing 0.5Fe–1Au–Ni/GDC showed an enhancing effect on the intrinsic electro-kinetics of the modified electrode. Specifically, the dependence of the polarization resistance on the pH2O was found to be strongly positive, resulting in a higher apparent reaction order, compared to Ni/GDC.
author2	Zaravelis, Fotios
author_facet	Zaravelis, Fotios Ζαραβέλης, Φώτιος Νιάκολας, Δημήτριος
author	Ζαραβέλης, Φώτιος Νιάκολας, Δημήτριος
author_sort	Ζαραβέλης, Φώτιος
title	Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study
title_short	Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study
title_full	Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study
title_fullStr	Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study
title_full_unstemmed	Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study
title_sort	enhancement of the intrinsic ni/gdc activity under rsoc operation by means of fe–au doping: an electro-kinetic study
publisher	International Journal of Hydrogen Energy
publishDate	2023
url	https://doi.org/10.1016/j.ijhydene.2023.06.034 https://hdl.handle.net/10889/25191
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Enhancement of the intrinsic Ni/GDC activity under rSOC operation by means of Fe–Au doping: An electro-kinetic study

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