Abstract
Le Chatelier's principle is a basic rule in textbook defining the correlations of reaction activities and specific system parameters (like concentrations), serving as the guideline for regulating chemical/catalytic systems. Here we report a model system breaking this constraint in O(2) electroreduction in mixed dioxygen. We unravel the central role of creating single-zinc vacancies in a crystal structure that leads to enzyme-like binding of the catalyst with enhanced selectivity to O(2), shifting the reaction pathway from Langmuir-Hinshelwood to an upgraded triple-phase Eley-Rideal mechanism. The model system shows minute activity alteration of H(2)O(2) yields (25.89~24.99 mol g(cat)(-1) h(-1)) and Faradaic efficiencies (92.5%~89.3%) in the O(2) levels of 100%~21% at the current density of 50~300 mA cm(-2), which apparently violate macroscopic Le Chatelier's reaction kinetics. A standalone prototype device is built for high-rate H(2)O(2) production from atmospheric air, achieving the highest Faradaic efficiencies of 87.8% at 320 mA cm(-2), overtaking the state-of-the-art catalysts and approaching the theoretical limit for direct air electrolysis (~345.8 mA cm(-2)). Further techno-economics analyses display the use of atmospheric air feedstock affording 21.7% better economics as comparison to high-purity O(2), achieving the lowest H(2)O(2) capital cost of 0.3 $ Kg(-1). Given the recent surge of demonstrations on tailoring chemical/catalytic systems based on the Le Chatelier's principle, the present finding would have general implications, allowing for leveraging systems "beyond" this classical rule.