Large-scale proton-exchange-membrane water electrolyzers (PEMWEs) are urgently needed for green hydrogen production, however, their development is largely hindered by the use of high-loading iridium in the anode. While amorphous IrOx catalysts with high activity exist, they typically follow either the lattice oxygen mechanism compromising stability, or the adsorbate evolution mechanism suffering from a high overpotential limit. Oxide path mechanism (OPM) offers a promising alternative by enabling direct *O─*O coupling, but its activation in the pure IrOx system remains challenging given the long distance between adjacent Ir atoms. Herein, we report a class of (La)IrOx porous amorphous catalyst with OPM pathway, featuring local unconventional hollandite phase and abundant water molecules inside its lattice tunnels. We demonstrate that such a unique short-range ordered structure can induce shortened Ir-Iredge distance and highly-active Ir≥5+ species, both contributing to desirable OPM for greatly enhanced catalytic performances. The as-assembled PEMWE achieves a cell voltage of 1.62 V at 1 A cm-2 with a low loading of 0.2 mgIr cm-2, and can operate stably over 500 h at industry-level current density. The accelerated stress test further validates its durability advantage at even lower 0.1 mgIr cm-2 loading, which validates its potential as a viable anode solution for durable low-iridium PEMWEs.
Keywords: amorphous iridium oxides; high‐valence Ir species; hollandite phase; oxygen evolution reaction; oxygen path mechanism.
© 2026 Wiley‐VCH GmbH.