化学
电极
三聚氰胺
电化学
检出限
电化学气体传感器
纳米技术
分子印迹聚合物
星团(航天器)
分子
电子转移
佩多:嘘
组合化学
光电子学
金属有机骨架
催化作用
结构异构体
线性范围
选择性
作者
Huihui Zhu,Tiantian Gong,Lijuan Chen,Junwei Zhao
标识
DOI:10.1021/acs.inorgchem.6c00426
摘要
Exploring and synthesizing polyoxometalates (POMs) with innovative building blocks (BBs) has become a key direction for advanced functional materials. In this work, a unique Ce3+-and-SeO32--cobridged asymmetric sandwich-type SbIII-SeIV-templated POM [H2N(CH3)2]2H6[Ce2(H2O)4][W2O4(HPA)2][SeSbW8O31][B-β-SeW8O30]·25H2O (1, HPA = 2-picolinic acid) was synthesized. The anionic framework of 1 features a unique asymmetric sandwich architecture, in which a heterometallic [Ce2(H2O)4W2O4(HPA)2]10+ cluster bridges a conventional tetravacant Keggin [B-β-SeW8O30]8- fragment and an uncommon {SeO3}-functionalized tetravacant Keggin [SeSbW8O31]7- moiety. Leveraging the exceptional electron storage and charge transfer capabilities of POMs, a hybrid 1-PEDOT film based on 1 and PEDOT (PEDOT = poly(3,4-ethylene dioxythiophene)) was fabricated and employed as an electrode modifier for the construction of a molecularly imprinted electrochemical sensor for the detection of melamine. The resulting sensor demonstrates high selectivity, excellent stability, a wide detection range (1 μM-10 pM), and a low detection limit of 1.95 × 10-12 M. This work provides an efficient strategy for designing and synthesizing new POM-based materials, enriches the structural and functional diversity of POMs, extends their applications in food safety monitoring, and realizes the transformation from molecular design to practical public health and environmental safety technologies.
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