Long-term-stability continuous flow CO2 reduction electrolysers with high current efficiency
Literature Information
Yueyuan Gu, Jucai Wei, Jindong Li, Xu Wu
One of the intrinsic problems relating to electrolysers for the electrochemical carbon dioxide reduction reaction is that the water-based liquid electrolyte induces the hydrogen evolution reaction. Here, we report an electrolyser based on a polymer electrolyte membrane and assisted by a high-performance advanced carbon-supported gold nanoparticle catalyst. By adjusting the mass ratio of gold in the catalyst, CO formation with up to 97% current efficiency was achieved at a cell potential of 2.7 V with 105 mA cm−2 partial current efficiency for CO production. The electrolyser has extremely high stability for 130 hours at 50 mA cm−2 with greater than 95% current efficiency and 55% energy efficiency for CO production. This work shows the great potential of using small-sized Au nanocatalysts with low gold content for the electrochemical reduction of CO2 in a full-cell. This strategy sheds light on the scale-up and further development of CO2 electrolysers aiming towards commercialization.
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