Ritsuki Nakajima scite author profile

Ritsuki Nakajima

2Publications

2Citation Statements Received

95Citation Statements Given

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Yokohama National University

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Structure and Activity of Electrolytically Deposited Hybrid Cobalt Hydroxide Nanosheet for Self-Repairing Oxygen Evolution Reaction Catalysts

Nakajima¹,

Taniguchi²,

Oishi³

et al. 2021

Meet. Abstr.

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Introduction Water electrolysis is a core technology in the conversion of renewable energy to hydrogen. Alkaline water electrolysis (AWE) is one of the most suitable technologies because of its low cost and applicability to large-scale production of hydrogen. However, the AWE system exhibits electrode degradation under fluctuating electricity from renewable energy. Recently, we have demonstrated the use of a hybrid cobalt hydroxide nanosheet (Co-ns) to form a self-repairing catalyst layer on a nickel anode under cycled potential,1 although formation process of catalyst layer and factors affecting the oxygen evolution reaction (OER) are not sufficiently understood. In this study, we investigated the catalyst formation process and activity via different deposition methods. Experimental Co-ns was synthesized according to the literature2. Electrochemical tests were performed in a 1.0 M KOH, using a PFA three-electrode cell. A nickel plate, a nickel coil, and a reversible hydrogen electrode were used as the working, counter, and reference electrodes, respectively. The surface Ni oxide/hydroxide was electrochemically removed by at －0.5 V vs. RHE for 3 min. The Co-ns dispersion (final concentration 40 ppm) was then added in the electrolyte. Co-ns was deposited by the two protocols. Cycled method is according to our previous report.1 The following processes were repeated for 8 or 30 times : i) chronopotentiometry (CP) at 800 mA cm-2 for 30 min, ii) cyclic voltammetry (CV) between 0.5 and 1.8 V vs. RHE at 5 mV s-1, iii) CV between 0.5 and 1.6 V vs. RHE at 50 mV s-1, iv) electrochemical impedance spectroscopy (EIS) at 1.6 V vs. RHE with the frequency range 0.1－105 Hz. The following deposition protocol, called the continuous method, was newly employed, where CP at 800 mA cm-2 for 4 or 15 hours was performed, followed by the above processes ii－iv once. Results and discussion The electrode prepared by the continuous method exhibited higher OER activity than those prepared by cycled method (Figure 1). The Co2+/3+ redox peaks appeared at different potential, suggesting a change in the composition and/or crystal structure (Figure 2), though little difference was observed in the XAS spectra. The charge of the anodic peaks due to Co2+/3+ (Q a) was used as a measure of the amounts of the deposited Co-ns. The current density at 1.6 V vs. RHE (i 1.6V) exhibited a linear relationship with Q a by the continuous method (Figure 3). Indicating that the catalytic activity is proportional to the amount of the deposited Co-ns. By the cycled method, the plots appeared on the same line as those obtained by the continuous method. Q a was monotonically increased up to the 15th cycle, whereas it turned to decrease after the cycle. Therefore, the OER activity depends hardly on the structure but on the amount of deposited Co-ns.To investigate the relationship between the morphology of the catalyst film and Q a, i 1.6V was plotted over the coverage of the electrode surface with Co-ns, estimated by the EDS mapping (Figure 4). The coverage increased a...

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Principles of Self‐Repairing Ability of Tripodal Ligand‐Stabilized Hybrid Cobalt Hydroxide Nanosheets for Alkaline Water Electrolysis

et al. 2023

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Self-repairing catalysts are promising new materials for achieving long lifetime of alkaline water electrolyzers powered by renewable energy. Catalytic nanoparticles dispersed in an electrolyte were deposited on the anode to repair a catalyst layer by electrolysis. A hybrid cobalt hydroxide nanosheet modified with tris(hydroxymethyl)aminomethane on the surface (Co-ns) was used as a catalyst. Assuming a pseudo-first-order process, the rate constant of an electrochemical deposition was linearly correlated with the electrode potential during electrol-ysis. Thus, it is expected that the repair of the catalyst is automatically controlled by changes in the oxygen evolution reaction (OER) overpotential. The essential step of the electrochemical deposition was the anodic oxidation of Co 2 + to Co 3 + . Surface modification of Co-ns protects Co 2 + against the autooxidation of Co 2 + caused by the dissolved oxygen. The redox properties and organic modification of Co-ns make them well-suited for the self-repairing of anode catalysts.

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