Abstract
Hydroquinone (HQ), a phenolic compound, poses substantial risks to human health due to its low degradability and high toxicity. Consequently, developing sensitive, accurate, and portable approaches for monitoring HQ is of significant importance. Herein, M-substituted (M=Cu, Mn, Ni, and La) Co3O4 nanocube (Co3O4 NC) was developed for improving the peroxidase-like activity of Co3O4 NC. Among these, Cu-substituted Co3O4 NC (Cu0.4Co2.6O4 NC) exhibited optimal peroxidase-like performance. Investigation into the catalytic mechanism revealed that the generation of hydroxyl radical and the increase of superoxide anion significantly enhanced the catalytic activity of Cu0.4Co2.6O4 NC. Cu0.4Co2.6O4 NC could catalyze the oxidation of 3,3′,5,5′-tetramethylbenzidine (TMB) with H2O2 to form a blue-color product. In the existence of HQ, the chromogenic reaction of TMB was inhibited due to the competition between HQ and TMB for the reactive oxygen species in the catalytic system. Additionally, a smartphone-mediated portable hydrogel sensor was integrated with color change to facilitate on-site detection. Furthermore, Cu0.4Co2.6O4 NC served as an electrocatalyst for electrochemical analysis of HQ. Considering these findings, we proposed a colorimetrical, hydrogel, and electrochemical multi-mode sensor for detecting HQ, showing wide linear ranges and low detection limits. The multi-mode sensor features self-verification for more reliable results and is suitable for various analysis conditions. It successfully determined HQ in real water samples, accompanied by consistent results with HPLC. This work not only provides an efficient pathway for developing nanozymes with superior catalytic properties but also demonstrates application potential in environmental protection.
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