化学
过氧化氢
聚酰亚胺
催化作用
共价键
氧化还原
光合作用
化学工程
组合化学
光化学
人工光合作用
高分子化学
共价有机骨架
有机化学
氢
动态共价化学
化学稳定性
聚合物
多相催化
单体
热稳定性
作者
Wei Zhao,Zhihua Li,Guanhua Ren,Jing Qi,Haiyang Huang,Qiang Zhu,Mounib Bahri,Yu-Lin Lu,Zekun Wang,Hui Li,Xiansong Shi,Binting Huang,Peiyao Yan,Chunqing Ji,Kexin Yu,Nigel D. Browning,Chaobin He,Haifeng Wang,Wei Zhang,Dan Zhao
摘要
Photocatalytic hydrogen peroxide (H 2 O 2 ) production offers a sustainable route for on-demand generation. Covalent organic frameworks (COFs) are attractive candidates, as their modular architectures can be engineered for optimal light capture and charge separation. However, their practical use has been hindered by the limited chemical stability of imine-linked COFs under prolonged operation. This challenge is further compounded by the narrow selection of building blocks suitable for efficient H 2 O 2 generation, restricting advancements in catalytic performance. Here, we present two polyimide-based COFs (NUS-76 and NUS-77) constructed with a newly designed fused-ring triphenylene building block, enabling efficient photocatalytic H 2 O 2 production. Utilizing a simple water-assisted microwave synthesis, both COFs exhibit remarkable robustness, retaining their crystalline structure even in strongly acidic and alkaline environments, outperforming the established imine-linked COF. Remarkably, NUS-77 integrates triphenylene and oligo(phenylenevinylene) moieties, delivering an impressive photocatalytic H 2 O 2 evolution rate up to 23,284 μmol g –1 h –1 . To further showcase their practical potential, we developed a continuous-flow photoreactor incorporating NUS-77, which produces 40.7 mM H 2 O 2 in 9 h and retains activity over four consecutive cycles (36 h) under 1 sun irradiation (P = 100 mW cm –2 ), a product concentration exceeding that of most reported COF photocatalysts. Theoretical calculations reveal that the imide linkage enhances charge separation and facilitates the formation of ·O 2 – intermediates during the catalytic redox cycle. Together, these findings illustrate how strategic engineering of linkages and building blocks effectively overcomes the stability limitations of COF-based photocatalysts, providing a viable pathway to durable frameworks for solar-to-chemical energy conversion.
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