Abstract
Water electrolysis, driven by renewable electricity, offers a sustainable path for hydrogen production. However, efficient bifunctional electrocatalysts are needed to overcome the high overpotentials of both the oxygen evolution reaction and hydrogen evolution reaction. To address this, a novel catalyst system is developed integrating plasmonic nanoreactors with chirality-induced spin selectivity. In this system, chiral Au nanoparticles act as antennae, while single-atom iridium serves as the catalytic reactor, achieving a 3.5 fold increase in reaction kinetics (at 1.57 V vs RHE) compared to commercial IrO(2) catalysts and enhancing durability by over 4.8 times relative to conventional Pt/C || IrO(2) systems. Density functional theory and operando X-ray absorption spectroscopy reveal that plasmon-driven spin alignment polarizes the Ir atom, significantly enhancing stability (>480 h at 100 mA cm(-2)) under acidic conditions. This work represents a major advance in spin polarization for plasmonic electrocatalysis, offering a new route to sustainable energy solutions.