Decoupling Bubble Nucleation from Catalysis to Boost Cu <sub> <i>x</i> </sub> O/NiO Electrocatalytic Water Splitting
Hanxiao Wang, Hanxiao Wang, Xiangdong Xue, Miaomiao Fan, Yucheng Dong, Hui Wang, Hui Wang, Wang Xuyun, Qing Dong, Wen Wang, Rongfang Wang, Jian Liu
Abstract
Efficient water splitting requires low overpotentials and mitigated bubble-induced mass transfer resistance at high current densities. However, the conflict between catalysis and bubble management intensifies at these currents, blocking mass transfer and rendering the catalytic sites inaccessible. Here, we embed Cu x O nucleation promoters in NiO nanosheet arrays to minimize overpotentials in electrochemical water splitting by decoupling bubble release from catalytic activity. Electrochemical measurements confirm a drastically reduced activation and mass transfer overpotential. Operando high-speed imaging combined with deep learning quantifies accelerated O 2 bubble dynamics at the Cu x O/NiO/NF interface. DFT calculations and Monte Carlo simulations show Cu x O acts as both O 2 bubble nucleation sites and a catalytic promoter for water splitting. An anion exchange membrane water electrolysis cell with Cu x O/NiO/NF delivers a current density of 3 A cm –2 at 2.13 V (ambient temperature). This bubble–catalysis–decoupling methodology and mechanistic insight will enable the rational design of advanced electrocatalytic systems for high-current density operation.