Covalent organic frameworks (COFs) have emerged as promising photocatalysts for hydrogen peroxide (H2O2) production, yet their performance is often limited by inefficient photogenerated charge separation and transport. Herein, a sp2 carbon-conjugated donor-acceptor-acceptor (D-A-A) COF (TFPT-TCPB-COF) incorporating a strong electron-withdrawing cyano group was rationally designed and synthesized via an optimized solvothermal method. The unique D-A-A architecture, together with abundant reductive active sites (triazine and cyano groups) for two-electron oxygen reduction and oxidative sites (benzene rings) for two-electron water oxidation, enables efficient H2O2 generation in pure water without sacrificial agents. As a result, TFPT-TCPB-COF achieves a high H2O2 production rate of 4.43 mmol g-1 h-1, which is 1.72 times greater than that of its imine-linked analogue (TFPT-TAPB-COF). Additionally, it exhibits an apparent quantum yield of 12.4% at 420 nm, outperforming most reported COF-based photocatalysts. Experimental and theoretical analyses reveal that the enhanced activity originates from improved charge separation and transport, as well as a modulated electronic structure that lowers the energy barriers for key *OOH and *OH intermediates during the photocatalytic process. This work provides important molecular insights into the design of advanced COF photocatalysts with donor-acceptor architectures for efficient solar energy conversion.
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Open Access
Research Article
Just Accepted
Open Access
Research Article
Just Accepted
The development of a dual Z-scheme photocatalytic system with stable and strong redox capability is essential for uranium recovery from nuclear wastewater and oceanic environments. Guided by density functional theory (DFT) calculations, an aerogel-like dual Z-scheme TiO2/g-C3N4/SnS2 (TCS) heterojunction photocatalyst is rationally designed for visible-light-driven uranium extraction. The TCS system achieves an exceptional uranium extraction efficiency of 99.1% within 120 min without the use of any sacrificial agents, which can be attributed to its aerogel architecture that offers a large specific surface area (211.7 m2/g) and abundant accessible active sites. Moreover, the presence of two synergistic Z-scheme electron transfer pathways significantly promotes the separation and migration of photogenerated charge carriers. Notably, the valence bands of both TiO2 and SnS2 enable ·OH generation, constructing a double-oxidized dual Z-scheme heterojunction that facilitates enhanced H2O2 production and thereby accelerates uranium extraction. Based on these findings, a comprehensive photocatalytic uranium extraction pathway and reaction mechanism are proposed, elucidating the roles of active species and the nature of the final extraction products.
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