Abstract

Bisphenol compounds (BPA, BPS, BPAF, etc.) are one class of the most important and widespread pollutants that poses severe threat to human health and the ecological environment. Because of the presence of multiple bisphenols in environmental and food samples, it is urgent and challenging to develop a rapid and cheap technique for simultaneously detecting BPA and its analogues. In this study, a series of M-N-C (M = Cu, Mg, Ni, Co, Fe, K) single-atom nanozymes (SAzymes) were created by simulating the structure of natural enzyme molecules, which were used as novel sensing platform for the fabrication of electrochemical sensors. Through systematic screening and characterization, it was interestingly discovered that the electrochemical sensor based on Cu-N-C SAzymes exhibited the best sensing performance for bisphenols among all SAzymes, which catalyzed not only BPA like tyrosinase, but also showed excellent catalytic capacity beyond tyrosinase (tyrosinase has no catalytic activity for BPS, BPAF, etc.), and achieved potential-resolved simultaneous rapid detection of BPA, BPS and BPAF. Further structure-activity relationship and catalytic mechanism characterizations of Cu-N-C SAzymes revealed that the presence of single atom Cu was predominantly in the form of Cu+ and Cu2+, which were anchored onto graphene nanosheet support through four coordination bonds with pyridinic N and pyrrolic N and acted as highly efficient active centers for electrocatalytic oxidation of bisphenols. The developed electrochemical sensing method exhibited excellent selectivity, sensitivity, and reliability for the rapid detection of multiple bisphenols in actual samples.

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