A sodium-ion-conducted asymmetric electrolyzer to lower the operation voltage for direct seawater electrolysis

Hydrogen produced from neutral seawater electrolysis faces many challenges including high energy consumption, the corrosion/side reactions caused by Cl(-), and the blockage of active sites by Ca(2+)/Mg(2+) precipitates. Herein, we design a pH-asymmetric electrolyzer with a Na(+) exchange membrane for direct seawater electrolysis, which can simultaneously prevent Cl(-) corrosion and Ca(2+)/Mg(2+) precipitation and harvest the chemical potentials between the different electrolytes to reduce the required voltage. In-situ Raman spectroscopy and density functional theory calculations reveal that water dissociation can be promoted with a catalyst based on atomically dispersed Pt anchored to Ni-Fe-P nanowires with a reduced energy barrier (by 0.26 eV), thus accelerating the hydrogen evolution kinetics in seawater. Consequently, the asymmetric electrolyzer exhibits current densities of 10 mA cm(−2) and 100 mA cm(−2) at voltages of 1.31 V and 1.46 V, respectively. It can also reach 400 mA cm(−2) at a low voltage of 1.66 V at 80 °C, corresponding to the electricity cost of US$1.36 per kg of H(2) ($0.031/kW h for the electricity bill), lower than the United States Department of Energy 2025 target (US$1.4 per kg of H(2)).