Abstract Electrocatalytic oxygen reduction reaction in seawater represents a sustainable approach for hydrogen peroxide (H 2 O 2) production, yet industrial-level current densities trigger severe cathodic alkalization and scaling issues, while aggressive acidification of the reaction system compromises catalytic efficiency. Here we show a cationic modification strategy that dynamically modulates the acidic electrified interface to promote both the formation and desorption of the key *OOH intermediate for H 2 O 2 synthesis. Enabled by this strategy, the cationic-modified catalysts achieve >90% efficiency at 500 mA cm -2 in natural seawater, and even reach 1. 125 A cm -2 in high-salinity electrolytes, with a competitive estimated cost of 0. 64 per kilogram of H 2 O 2. Ab initio molecular dynamics simulations reveal that the introduced cationic modifications effectively counteract O–O bond cleavage induced by both the inherent strong binding of catalytic sites and the potential-induced over-binding effect under highly negative potentials, and thus facilitate *OOH desorption for H 2 O 2 formation. This work highlights dynamic interfacial intermediate stabilization as a strategy that complements conventional static binding-energy tuning, enabling high-current-density H 2 O 2 electrosynthesis in seawater.
Cao et al. (Mon,) studied this question.