A comprehensive study of the kinetics of hydrogen peroxide reduction reaction by rotating disk electrode

•A new equation is derived to study the H2O2 reduction reaction (HPRR) by RDE.•A methodology is presented to predict the mechanism of HPRR by the new equation.•The new equation is more applicable than Koutecky–Levich equation to study HPRR.•HPRR is studied on N-doped graphene by the new equation and...

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Veröffentlicht in:	Electrochimica acta 2013-12, Vol.114, p.551-559
Hauptverfasser:	Amirfakhri, Seyed Javad, Meunier, Jean-Luc, Berk, Dimitrios
Format:	Artikel
Sprache:	eng
Schlagworte:	Electrodes H2O2 decomposition rate constant Hydrogen peroxide Hydrogen peroxide reduction reaction (HPRR) Inverse Koutecky–Levich equation Mathematical analysis N-doped graphene Rate constants Reduction Reduction (electrolytic) Rotating disk electrode (RDE) Rotating disks
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creator	Amirfakhri, Seyed Javad Meunier, Jean-Luc Berk, Dimitrios
description	•A new equation is derived to study the H2O2 reduction reaction (HPRR) by RDE.•A methodology is presented to predict the mechanism of HPRR by the new equation.•The new equation is more applicable than Koutecky–Levich equation to study HPRR.•HPRR is studied on N-doped graphene by the new equation and described methodology. This work presents a methodology to analyze hydrogen peroxide reduction reaction (HPRR) studied by rotating disk electrode (RDE). Generally the Koutecky–Levich equation is used to determine the kinetic parameters of an electrochemical reaction. This equation is not applicable to electrochemical reactions with a complex reaction mechanism. The HPRR is an example of these complex reactions because the H2O2 reduction, H2O2 decomposition and O2 reduction may take place simultaneously on the electrode surface. In the current work the mass transport equations of H2O2 in the electrolyte and the reaction equations on the electrode surface are solved simultaneously under the steady state conditions to derive a specific equation for HPRR. The new equation shows the same linear relationship between the inverse of the current density (j−1) and the inverse square root of the rotation frequency (ω−1/2), but the slopes and the intercepts of the lines are shown to be functions of the reaction rate constants involved in the HPRR. One of the most important results of the work is the possibility to determine the hydrogen peroxide decomposition rate constant directly from RDE data. Prediction of simultaneous reduction of H2O2 and O2 on the electrode and suggestion a mechanism for HPRR are other advantages of the derived equation when compared with Koutecky–Levich equation.
doi_str_mv	10.1016/j.electacta.2013.10.094
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This work presents a methodology to analyze hydrogen peroxide reduction reaction (HPRR) studied by rotating disk electrode (RDE). Generally the Koutecky–Levich equation is used to determine the kinetic parameters of an electrochemical reaction. This equation is not applicable to electrochemical reactions with a complex reaction mechanism. The HPRR is an example of these complex reactions because the H2O2 reduction, H2O2 decomposition and O2 reduction may take place simultaneously on the electrode surface. In the current work the mass transport equations of H2O2 in the electrolyte and the reaction equations on the electrode surface are solved simultaneously under the steady state conditions to derive a specific equation for HPRR. The new equation shows the same linear relationship between the inverse of the current density (j−1) and the inverse square root of the rotation frequency (ω−1/2), but the slopes and the intercepts of the lines are shown to be functions of the reaction rate constants involved in the HPRR. One of the most important results of the work is the possibility to determine the hydrogen peroxide decomposition rate constant directly from RDE data. 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This work presents a methodology to analyze hydrogen peroxide reduction reaction (HPRR) studied by rotating disk electrode (RDE). Generally the Koutecky–Levich equation is used to determine the kinetic parameters of an electrochemical reaction. This equation is not applicable to electrochemical reactions with a complex reaction mechanism. The HPRR is an example of these complex reactions because the H2O2 reduction, H2O2 decomposition and O2 reduction may take place simultaneously on the electrode surface. In the current work the mass transport equations of H2O2 in the electrolyte and the reaction equations on the electrode surface are solved simultaneously under the steady state conditions to derive a specific equation for HPRR. The new equation shows the same linear relationship between the inverse of the current density (j−1) and the inverse square root of the rotation frequency (ω−1/2), but the slopes and the intercepts of the lines are shown to be functions of the reaction rate constants involved in the HPRR. One of the most important results of the work is the possibility to determine the hydrogen peroxide decomposition rate constant directly from RDE data. 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subjects	Electrodes H2O2 decomposition rate constant Hydrogen peroxide Hydrogen peroxide reduction reaction (HPRR) Inverse Koutecky–Levich equation Mathematical analysis N-doped graphene Rate constants Reduction Reduction (electrolytic) Rotating disk electrode (RDE) Rotating disks
title	A comprehensive study of the kinetics of hydrogen peroxide reduction reaction by rotating disk electrode
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