The high energy consumption and production of undesired oxygen greatly restrict the wide adoption of water electrolysis for hydrogen production.In a paper recently published in Nature Catalysis,Wang and coworkers rati...The high energy consumption and production of undesired oxygen greatly restrict the wide adoption of water electrolysis for hydrogen production.In a paper recently published in Nature Catalysis,Wang and coworkers rationally introduce aldehydes for oxidation at anode to replace oxygen evolution reaction,which can produce hydrogen and value-added products at low potential,realizing efficient bipolar hydrogen production with highpurity.Moreover,these aldehydes are biomass-derived and contribute to sustainable hydrogen production.展开更多
基金supported by National Science Fund for Distinguished Young Scholars(No.52025133)Youth Innovation Promotion Association(No.202055)+1 种基金the National Natural Science Foundation of China(No.22105007)the China Postdoctoral Science Foundation(No.2020M670018).
文摘The high energy consumption and production of undesired oxygen greatly restrict the wide adoption of water electrolysis for hydrogen production.In a paper recently published in Nature Catalysis,Wang and coworkers rationally introduce aldehydes for oxidation at anode to replace oxygen evolution reaction,which can produce hydrogen and value-added products at low potential,realizing efficient bipolar hydrogen production with highpurity.Moreover,these aldehydes are biomass-derived and contribute to sustainable hydrogen production.
