Hybrid lead halides are promising photocatalysts due to high structural tunability and excellent photophysical properties, but their ionic structures suffer from instability in polar environment and suppressed charge transfer between lead halide units and organic components. Herein, we successfully incorporated a ferrocene-based light-harvesting antenna into a lead iodide framework by coordination-driven assembly. The π-conjugated Pb2+-carboxylate linkage affords synergistic interactions between [Pb2I2]2+ chains and ferrocene linkers, achieving broad visible absorption up to 612.7 nm and efficient ligand-to-metal charge transfer for spatial charge separation. This ultrastable framework combines strong visible-light absorption of ferrocene centers with excellent charge transport of lead halide units, achieving 6e− CO2 photoreduction to CH3OH coupled with ethanol oxidation. Mechanistic studies reveal that ferrocene photoexcitation followed by linker-to-metal charge transfer significantly enhance carrier accumulation, accelerating the CH3O* intermediate formation as mapped by in-situ spectroscopy and theoretical calculations.
