In situ generated Fe 3 C embedded Fe-N-doped carbon nanozymes with enhanced oxidase mimic activity for total antioxidant capacity assessment.
Rui LiXiaohong QiaoHuijun MaHanmei LiCong LiLi Hua JinPublished in: Journal of materials chemistry. B (2022)
In this work, we reported new Fe 3 C embedded Fe-N-doped carbon nanomaterials (Fe 3 C@Fe-N-CMs) generated in situ by the facile pyrolysis of Fe-Zn ZIF precursors. The resulting Fe 3 C@Fe-N-CMs were equipped with several desirable nanozyme features, including multiple efficient intrinsic active sites ( i.e. Fe-N x , Fe 3 C@C, and C-N moieties), large specific surface area and abundant mesoporous structures. As a result, these Fe 3 C@Fe-N-CMs displayed exceptional ability to mimic three enzymes: peroxidase, catalase and oxidase, while the Fe 3 C@Fe-N-CMs pyrolyzed at 800 °C, named CMs-800, showed the best enzyme-like properties. After systematically investigating the catalytic mechanism, we further explored the application of the oxidase-like properties of CMs-800 in the detection of the total antioxidant capacity (TAC) in beverages and tablets. This study not only provided a new approach to construct multifunctional carbon-based nanozymes, but also expanded the application of carbon nanozymes in the field of food quality and safety.