Bubble-induced versus thermodynamic voltage losses during pressurized alkaline water electrolysis
Hannes Rox, Feng Liang, Robert Baumann, Mateusz M. Marzec, Krystian Soko{\l}owski, Xuegeng Yang, Andr\'es F. Lasagni, Roel van de Krol, Kerstin Eckert
TL;DR
This study investigates how bubble size and pressure influence voltage losses in pressurized alkaline water electrolysis, revealing that smaller bubbles at higher pressures can offset thermodynamic losses.
Contribution
It demonstrates that bubble size manipulation at elevated pressures can reduce voltage losses, combining experimental data with Buckingham {\
Findings
Bubble sizes decrease as pressure increases.
Larger pillar sizes lead to bigger bubbles at all pressures.
Increasing current density reduces overpotential despite higher pressure.
Abstract
Understanding how bubbles influence the efficiency of water electrolysis is crucial to achieve economically competitive hydrogen, generated by renewable energy sources, such as wind and solar power. Water electrolysis is typically performed at high pressures to reduce the cost of energy-intensive mechanical compression of the produced H2. Thus, a better understanding of how the absolute pressure affects electrochemical performance and bubble size is necessary. In general, bubble sizes decrease as the pressure increases. Using different-sized pillar-patterned Ni electrodes generated by Direct Laser Writing, the detached bubble sizes can be modified even at elevated pressures. As the pillar size increases, the bubbles become larger at all pressures investigated from 1 to 6 bar. At a current density of -25 mA/cm2, the cathodic potential increases with pressure according to the…
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