Determination of electrochemically active surface and fractal properties of oxide electrodes by voltammetry

Содержание журнала №2 за 2022 год

Информация о статье:

DOI	10.47188/0869-5326_2022_30_2_23
Раздел/Section	Электроосаждение металлов и сплавов	Electroplating of metals and alloys
Заглавие/Title	Determination of electrochemically active surface and fractal properties of oxide electrodes by voltammetry	Determination of electrochemically active surface and fractal properties of oxide electrodes by voltammetry
Авторы/Authors	A.A. Trofimov, V.M. Rudoi, T.S. Trofimova, T.N. Ostanina	A.A. Trofimov, V.M. Rudoi, T.S. Trofimova, T.N. Ostanina
Страницы/Pages	23-31
Ключевые слова Keywords	fractal, oxygen evolution reaction, fractal scale, electrocatalysis, electrodeposition, cyclic voltammetry
Аннотация Description		Catalytic activity of electrodes towards oxygen evolution reaction was assessed using electrochemically active surface. Paper introduces a new approach using peak current from cyclic voltammetry for the determination of the catalyst surface area with regards to the fractal properties of the electrode using diffusion layer thickness as a scale bar. Three oxide electrode materials: NiCo₂O₄, Co₃O₄ and air-oxidized Ni have been prepared by electrodeposition on a nickel substrate (Fig. 1, 4). Cyclic voltammetry in system with Fe³⁺/Fe²⁺ red-ox pair (Fig. 2) has been used for active surface area determination. Scaling equation for the determination of fractal dimension and surface area from the dependence of peak current on potential scan rate in a system with red-ox reaction has been derived (Fig. 3, 5). The surface of the electrode with nickel cobaltite layer demonstrated fractal properties with fractal dimension of 2.33 ± 0.15 (Fig. 5). Electrochemically active surface of fractal NiCo₂O₄ increased by 60% when scan rate was changing from 20 to 500 mV/s, while Ni and Co₃O₄ active surface remained constant at 1,07±0,07 and 1,67 ± 0,10 cm² respectively (Table 1). Voltamperograms at different scan rates recalculated for current density using active surface areas are similar (Fig.6) for different electrodes. Maijor factor affecting NiCo₂O₄ performance towards oxygen evolution is more extensive factor, than its catalytic activity.
Ссылка на Link for citation	A.A. Trofimov, V.M. Rudoi, T.S. Trofimova, T.N. Ostanina. Determination of electrochemically active surface and fractal properties of oxide electrodes by voltammetry // Гальванотехника и обработка поверхности. 2022. Том 30, № 2. С.23-31. doi: 10.47188/0869-5326_2022_30_2_23	A.A. Trofimov, V.M. Rudoi, T.S. Trofimova, T.N. Ostanina. Determination of electrochemically active surface and fractal properties of oxide electrodes by voltammetry // Galvanotekhnika i obrabotka poverkhnosti. 2022. Vol.30, № 2. P.23-31. doi: 10.47188/0869-5326_2022_30_2_23
Текст/Text	http://elibrary.ru/item.asp?id=49062672