Amorphous WO induced lattice distortion for a low-cost and high-efficient electrocatalyst for overall water splitting in acid

The development of highly active and durable catalysts for water oxidation under acidic conditions is necessary but challenging for renewable energy conversion. Ir-based catalysts are highly efficient for water oxidation in acid, but their large scale application is hindered by the high cost and scarcity of iridium. Herein, we use an amorphous WO 3 induced lattice distortion (AWILD) strategy to reduce the Ir content to only 2 wt% in the final material. The optimized hybrid nitrogen-doped carbon (NC)/WO 3 /IrO 2 can efficiently catalyze water oxidation with a low overpotential of 270 mV at 10 mA cm −2 current density ( η 10 ) and a high turnover frequency of over 2 s −1 at 300 mV overpotential in 0.5 M H 2 SO 4 , a performance that surpasses that of commercial IrO 2 significantly. Introducing the layer of amorphous WO 3 between IrO 2 nanoparticles and NC can distort the lattice of IrO 2 , exposing more highly active sites for water oxidation. The AWILD effect compensates for the lower Ir content and dramatically reduces the cost of the catalyst without sacrificing the catalytic activity. Additionally, this catalyst also exhibits high activity in acid for hydrogen evolution with only 65 mV of η 10 attributed to the AWILD effect, exhibiting efficient bifunctionality as a Janus catalyst for overall water splitting. The AWILD approach provides a novel and efficient strategy for low-cost and highly efficient electrocatalysts for acidic overall water splitting with an extremely low content of noble metals. An amorphous WO 3 induced lattice distortion strategy leads to only 2 wt% Ir for efficient overall water splitting in acid.