A Unique Fe-N4 Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic C-H Activation with High Efficiency and Selectivity

Selective oxidation of C-H bonds is one of the most important reactions in organic synthesis. However, activation of the alpha-C-H bond of ethylbenzene by use of photocatalysis-generated superoxide anions (O-2(center dot-)) remains a challenge. Herein, the formation of individual Fe atoms on polymeric carbon nitride (CN), that activates O-2 to create O-2(center dot-) for facilitating the reaction of ethylbenzene to form acetophenone, is demonstrated. By utilizing density functional theory and materials characterization techniques, it is shown that individual Fe atoms are coordinated to four N atoms of CN and the resultant low-spin Fe-N-4 system (t(2g)(6)e(g)(0)) is not only a great adsorption site for oxygen molecules, but also allows for fast transfer of electrons generated in the CN framework to adsorbed O-2, producing O-2(center dot-). The oxidation reaction of ethylbenzene triggered by O-2(center dot-) ions turns out to have a high conversion rate of 99% as well as an acetophenone selectivity of 99%, which can be ascribed to a novel reaction pathway that is different from the conventional route involving hydroxyl radicals and the production of phenethyl alcohol. Furthermore, it possesses great potential for other C-H activation reactions besides ethylbenzene oxidation.

Automated summary

This study demonstrates a new method utilizing individual iron atoms on polymeric carbon nitride to activate superoxide anions for promoting the oxidation reaction of ethylbenzene, resulting in high conversion rate and selectivity.