Polarization engineering of ether-embedded covalent organic frameworks for boosting photocatalytic H(2)O(2) production from seawater.

Visible light-driven hydrogen peroxide (HO) production from natural seawater over covalent organic frameworks (COFs) is becoming a challenge. In this work, a polarization strategy via incorporating oxo-ether (O) functional groups into COFs architecture was attempted and demonstrated to significantly enhance photocarriers separation. The strategy interestingly transformed the COFs morphology from rod-like flower clusters to sheet-like flower clusters. Furthermore, the monomer 4,4'-oxydianiline (OD) of the oxo-ether functionalized COFs (TpOD-COF) obtained a cost efficiency that was about 1794 times higher than the monomer benzidine (BD) formed non-functionalized COFs (TpBD-COF). TpOD-COF in real seawater achieved 4598 μmol·g·h of HO productivity, and 10.2% of apparent quantum yield (AQY) without electron-proton donors and pure oxygen (O), which was 1.91 times higher than TpBD-COF. Mechanism studies revealed that TpOD-COF not only satisfies the thermodynamic requirement for the 2e oxygen reduction reaction, but also indirectly enhances HO production through water oxidation, thereby establishing a cycle system that goes from water (HO) to O and then indirectly to HO, which promotes the overall reaction kinetics. More importantly, the catalyst did not deactivate in seawater; instead, the presence of ions further promoted electron transfer. Furthermore, the polar oxygen atoms served as additional hydrogen bond acceptors, enhancing the hydrogen-bonding network architecture. The system suggested a powerful functional-groups-mediated polarization engineering for the development of highly efficient metal-free photocatalysts.