近日,2022级硕士生熊庆浩在SCI二区期刊Microchemical Journal (IF=4.9) 发表基于Ni-MOF@COFTAPB-DVA蛋黄壳结构复合材料的高选择性多巴胺电化学传感器“High-selective dopamine electrochemical sensor based on yolk-shell structural composites derived from Ni-MOF@COFTAPB-DVA”。
原文链接:https://doi.org/10.1016/j.microc.2025.112987
Abstract
Covalent-organic frameworks (COF) and metal–organic frameworks (MOF) were promising precursors for porous carbon-based materials. Calcining individual COF or MOF is usually unfavorable when preparing electrochemical active materials that combine sensitivity, stability, and selectivity. In this work, calcining a core–shell structural Ni-MOF@COFTAPB-DVA prepared a yolk-shell structural composite (YS-Ni@NC), in which the N-doped carbon shell (NC) encapsulated the Ni nanoparticles yolk (NiNPs). A highly selective dopamine electrochemical sensor (YS-Ni@NC/GCE) was developed based on the YS-Ni@NC modified glassy carbon electrode (GCE). The NiNPs yolk in the derivates provided excellent electrocatalytic activity, and the N-doped carbon shell improved the composite conductivity, enhanced the structural stability, and reduced the nonspecific adsorption of uric acid and ascorbic acid through electrostatic repulsion force. The YS-Ni@NC/GCE electrode exhibited higher selec tivity for dopamine than the control electrodes in the presence of uric acid and ascorbic acid due to the elec trostatic interaction between YS-Ni@NC and the small molecules. At the optimal experimental conditions, the DA sensor showed a linear concentration range of 0.136~70.0 μ M with a detection limit of 0.041 μ M. In addition, the electrochemical performance of the sensor was stable when stored at room temperature for 30 days. Prep aration of the yolk-shell structural MOF@COF derivates provided a new approach for fabricating highly selective non-enzymatic dopamine electrochemical sensors.
Scheme 1. Schematic illustration of synthesis and application of YS-Ni@NC600 microspheres.