Controllable Cyclopalladated Polythiophene Imine Monolayer by Self-Assembly, Hybrid Doping and Electrochemical Polymerization: A Simple Way to Enhance Activity and Stability

Catalysis Research Pub Date : 2021-12-13 DOI:10.21926/cr.2201003
Louguangshu Huang, Hui Liu, Xiaoxia Xue, Wuduo Zhao, Tiesheng Li
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引用次数: 1

Abstract

In this article, an approach to generate self-assembly cyclopalladated polythiophene imine monolayers (denoted as ITO@Pd-CPTIMs) is described. The monolayers were fabricated by combining self-assembly (SA), hybrid doping (HD), and electrochemical polymerization (ECP) called SA-HD-ECP. The catalytic activity and stability of the polymerized monolayers in the Suzuki coupling reaction were improved by modulating the structure and morphology in hybrid doping using different thiophene derivatives, concentrations, and scanning numbers during electrochemical polymerization. Morphological changes in the catalytic surface associated with catalytic activity were investigated. ITO@Pd-PTF could improve catalytic activity with a higher TON value (45000 mol/molcat) and attain recycling ability at least 10 times.
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自组装、杂化掺杂和电化学聚合的可控环钯化聚噻吩亚胺单分子膜:一种提高活性和稳定性的简单方法
在这篇文章中,一种方法来产生自组装环钯化聚噻吩亚胺单层(表示为ITO@Pd-CPTIMs)被描述。采用自组装(SA)、杂化掺杂(HD)和电化学聚合(ECP)相结合的方法制备单层膜,称为SA-HD-ECP。通过在电化学聚合过程中使用不同的噻吩衍生物、浓度和扫描次数来调节杂化掺杂的结构和形态,提高了铃木偶联反应中聚合单层膜的催化活性和稳定性。研究了催化表面的形态变化与催化活性的关系。ITO@Pd-PTF可以提高催化活性,具有较高的TON值(45000 mol/molcat),达到至少10次的循环能力。
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Catalysis Research
Catalysis Research
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