The impact mechanism of Mn2+ ions on oxygen evolution reaction in zinc sulfate electrolyte

• Published in: Journal of electroanalytical chemistry (Lausanne, Switzerland) Vol. 811; pp. 53 - 61
• Main Authors: Zhang, Chenmu, Duan, Ning, Jiang, Linhua, Xu, Fuyuan
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 15.02.2018
• Subjects: Activation energy; Energy consumption; Heavy metal pollutants; Mn2+ ions; Oxygen evolution reaction; Energy consumption; Heavy metal pollutants; Mn2+ ions; Oxygen evolution reaction; Activation energy
• ISSN: 1572-6657; 1873-2569
• DOI: 10.1016/j.jelechem.2018.01.040

The impact mechanism of Mn2+ on the oxygen evolution reaction (OER) on the fresh lead-based anode in zinc sulfate electrolyte has been studied in detail by several electrochemical methods, XRD, SEM and EDX. The kinetics analysis suggested that the Mn2+ could significantly enhance OER, which was controlled by the electron transfer process between the active site S and H2O (step (2)). This positive effect of Mn2+ on OER was limited with the increase of Mn2+ because of the approaching saturation of active sites. Results obtained from the Arrhenius equation disclosed the larger bond strength of MnO2-OH in decreasing the activation energy of OER (from 55.08 to 47.04 kJ/mol), meanwhile, it also further supported the fact that the OER was electrochemical-controlled and it would not be changed in essence with the addition of Mn2+, which is subject to the activation energy barrier of electron transfer induced by the active site S (step (2)). EIS data revealed adsorption resistance of the intermediate (S-OHads), Ra played a major role among the whole reaction resistance, whereas, the impact contribution of charge transfer resistance, Rt became larger as the Mn2+ increases, which revealed that the inhibition of electron transfer process due to the changes of the anode surface microstructure. Electron microscope technology suggested the key role Mn2+ played in the modification of the active interface structure, and its influence process on OER was revealed by the microstructure analysis of anode surface. Considering the potential of Mn2+ concentration optimization in reducing heavy metal pollutants and energy consumption, enhancing the understanding of impact mechanism of Mn2+ on OER provides a feasible proposal in zinc electrolysis industry.