The green hydrogen economy is important for carbon neutrality, but industrial-scale water electrolysis needs improvement in efficiency, operation costs, and capital costs. A detailed understanding of bubble behavior in water electrolyzers is necessary to control bubbles. This study investigates how electrolyte properties affect bubble detachment sizes and establishes a quantitative relationship to regulate bubble management through electrolyte engineering.
The green hydrogen economy is expected to play a crucial role in carbon neutrality, but industrial-scale water electrolysis requires improvements in efficiency, operation costs, and capital costs before broad deployment. Electrolysis operates at a high current density and involves the substantial formation of gaseous products from the electrode surfaces to the electrolyte, which may lead to additional resistance and a resulting loss of efficiency. A detailed clarification of the bubble departure phenomena against the electrode surface and the surrounding electrolytes is needed to further control bubbles in a water electrolyzer. This study clarifies how electrolyte properties affect the measured bubble detachment sizes from the comparisons with analytical expressions and dynamic simulations. Bubble behavior in various electrolyte solutions and operating conditions was described using various physical parameters. A quantitative relationship was then established to connect electrolyte properties and bubble departure diameters, which can help regulate the bubble management through electrolyte engineering.
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