Two-step decoupled electrolysis approach based on pseudocapacitive WO3 auxiliary electrode.

Hydrogen production via electrolysis is an efficient way to store excess energy from renewable energy plants, but electrolysis must be made more applicable. Conventional water electrolysis is complicated by a gas distribution and management system to prevent the mixing of H 2 and O 2 gases, which creates significant safety hazards. The use of membranes and diaphragms solves the gas mixing problem but reduces efficiency and directly affects the cost of hydrogen production. Here we show decoupled water electrolysis concept, where hydrogen evolution and oxygen evolution are spatially and temporally separated using a WO 3 charge storage electrode as a red-ox mediator. Electrolysis is realized in two steps, where in the first step the oxygen evolution reaction (OER) and intercalation of H+ in the WO 3 material take place. In the second step, the deintercalation of H+ from the WO 3 material and the reduction of H+ to H at the other electrode takes place. In the electrolysis process H 2 and O 2 gasses are produced with purity >99.9%. The overall efficiency of the electrolyzer is 65%. [Display omitted] • Hydrogen evolution and oxygen evolution has been spatially and temporally separated. • Acid electrolyser of primary Pt electrode in connection with pseudocapacitive WO 3. • Acid decoupled H 2 O electrolysis produces gasses in two-step process with high purity. [ABSTRACT FROM AUTHOR]