High quantum efficiency of hydrogen production from methanol aqueous solution with PtCu-TiO 2 photocatalysts.
Hui WangHaifeng QiXiao SunShuya JiaXiyi LiTina Jingyan MiaoLunqiao XiongShihao WangXiaolei ZhangXiao Yan LiuAiqin WangTao ZhangWei-Xin HuangJunwang TangPublished in: Nature materials (2023)
Methanol with 12.5 wt% H 2 content is widely considered a liquid hydrogen medium. Taking into account water with 11.1 wt% H 2 content, H 2 synthesis from the mixture of water and methanol is a promising method for on-demand hydrogen production. We demonstrate an atomic-level catalyst design strategy using the synergy between single atoms and nanodots for H 2 production. The PtCu-TiO 2 sandwich photocatalyst achieves a remarkable H 2 formation rate (2,383.9 µmol h -1 ) with a high apparent quantum efficiency (99.2%). Furthermore, the oxidation product is a high-value chemical formaldehyde with 98.6% selectivity instead of CO 2 , leading to a nearly zero-carbon-emission process. Detailed investigations indicate a dual role of the copper atoms: an electron acceptor to facilitate photoelectron transfer to Pt, and a hole acceptor for the selective oxidation of methanol to formaldehyde, thus avoiding over-oxidation to CO 2 . The synergy between Pt nanodots and Cu single atoms together reduces the activation energy of this process to 13.2 kJ mol -1 .