Influence and Electrochemical Stability of Oxygen Groups and Edge Sites in Vanadium Redox Reactions

It is widely accepted that surface‐active oxygen functional groups (OFGs) effectively catalyze the vanadium redox reactions. Initial graphitic edge sites, OFGs and their electrochemical stability were examined using graphite felts, which were modified with multi‐walled carbon nanotubes and activated...

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Veröffentlicht in:	ChemElectroChem 2020-12, Vol.7 (23), p.4745-4754
Hauptverfasser:	Radinger, Hannes, Pfisterer, Jessica, Scheiba, Frieder, Ehrenberg, Helmut
Format:	Artikel
Sprache:	eng
Schlagworte:	Activated carbon carbon nanotubes Chemical reactions Correlation Electrochemistry Functional groups graphite felt electrodes graphitic defects Multi wall carbon nanotubes Oxidation Oxygen oxygen functional groups Redox reactions Stability Vanadium vanadium flow battery
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creator	Radinger, Hannes Pfisterer, Jessica Scheiba, Frieder Ehrenberg, Helmut
description	It is widely accepted that surface‐active oxygen functional groups (OFGs) effectively catalyze the vanadium redox reactions. Initial graphitic edge sites, OFGs and their electrochemical stability were examined using graphite felts, which were modified with multi‐walled carbon nanotubes and activated with KOH. It is demonstrated that OFGs cannot exclusively be responsible for the electrocatalysis since they did not correlate to the electrochemical activity. The surface composition after electrochemical cycling in the positive half‐cell was still different for all samples but did not reflect the performance either. However, a correlation was found between the activity and stable edge site defects. There was neither a correlation between the electrocatalytic activity and the amount of oxygen, nor for the kind of OFG in the negative half‐cell. The oxygen concentration after electrochemistry was very similar, even more highlighting the importance of edge sites in the VIII/VII redox reaction. The results of this work indicate that the major electrocatalytic effect for both half‐cell redox reactions is related to stable graphitic edge sites in sufficient quantity. Closer to the edge: Oxygen groups are not exclusively responsible for the #electrocatalysis of the vanadium redox reactions. Edge sites, however, catalyze the VVO2+/VIVO2+ and the VIII/VII half‐cell reactions. This study highlights the importance of their electrochemical stability in contrast to dynamically evolving oxygen functional groups by studying the properties of graphite felt electrodes before and after electrochemistry.@hannes radinger
doi_str_mv	10.1002/celc.202001387
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Initial graphitic edge sites, OFGs and their electrochemical stability were examined using graphite felts, which were modified with multi‐walled carbon nanotubes and activated with KOH. It is demonstrated that OFGs cannot exclusively be responsible for the electrocatalysis since they did not correlate to the electrochemical activity. The surface composition after electrochemical cycling in the positive half‐cell was still different for all samples but did not reflect the performance either. However, a correlation was found between the activity and stable edge site defects. There was neither a correlation between the electrocatalytic activity and the amount of oxygen, nor for the kind of OFG in the negative half‐cell. The oxygen concentration after electrochemistry was very similar, even more highlighting the importance of edge sites in the VIII/VII redox reaction. The results of this work indicate that the major electrocatalytic effect for both half‐cell redox reactions is related to stable graphitic edge sites in sufficient quantity. Closer to the edge: Oxygen groups are not exclusively responsible for the #electrocatalysis of the vanadium redox reactions. Edge sites, however, catalyze the VVO2+/VIVO2+ and the VIII/VII half‐cell reactions. This study highlights the importance of their electrochemical stability in contrast to dynamically evolving oxygen functional groups by studying the properties of graphite felt electrodes before and after electrochemistry.@hannes radinger</description><identifier>ISSN: 2196-0216</identifier><identifier>EISSN: 2196-0216</identifier><identifier>DOI: 10.1002/celc.202001387</identifier><language>eng</language><publisher>Weinheim: John Wiley & Sons, Inc</publisher><subject>Activated carbon ; carbon nanotubes ; Chemical reactions ; Correlation ; Electrochemistry ; Functional groups ; graphite felt electrodes ; graphitic defects ; Multi wall carbon nanotubes ; Oxidation ; Oxygen ; oxygen functional groups ; Redox reactions ; Stability ; Vanadium ; vanadium flow battery</subject><ispartof>ChemElectroChem, 2020-12, Vol.7 (23), p.4745-4754</ispartof><rights>2020 The Authors. ChemElectroChem published by Wiley-VCH GmbH</rights><rights>2020. 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Initial graphitic edge sites, OFGs and their electrochemical stability were examined using graphite felts, which were modified with multi‐walled carbon nanotubes and activated with KOH. It is demonstrated that OFGs cannot exclusively be responsible for the electrocatalysis since they did not correlate to the electrochemical activity. The surface composition after electrochemical cycling in the positive half‐cell was still different for all samples but did not reflect the performance either. However, a correlation was found between the activity and stable edge site defects. There was neither a correlation between the electrocatalytic activity and the amount of oxygen, nor for the kind of OFG in the negative half‐cell. The oxygen concentration after electrochemistry was very similar, even more highlighting the importance of edge sites in the VIII/VII redox reaction. The results of this work indicate that the major electrocatalytic effect for both half‐cell redox reactions is related to stable graphitic edge sites in sufficient quantity. Closer to the edge: Oxygen groups are not exclusively responsible for the #electrocatalysis of the vanadium redox reactions. Edge sites, however, catalyze the VVO2+/VIVO2+ and the VIII/VII half‐cell reactions. 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subjects	Activated carbon carbon nanotubes Chemical reactions Correlation Electrochemistry Functional groups graphite felt electrodes graphitic defects Multi wall carbon nanotubes Oxidation Oxygen oxygen functional groups Redox reactions Stability Vanadium vanadium flow battery
title	Influence and Electrochemical Stability of Oxygen Groups and Edge Sites in Vanadium Redox Reactions
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