Effects of Polydopamine Incorporation on the Nanostructure and Electrochemical Performance of Electrodeposited Polypyrrole Films

C Pub Date : 2024-02-20 DOI:10.3390/c10010020
James A. Behan, Frédéric Barrière
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Abstract

Polypyrrole films are commonly prepared as conductive electrode surfaces for a variety of applications. Recently, there has been increasing interest in improving the adhesive properties and biocompatibility of polypyrrole electrodes via the incorporation of bioinspired polydopamine within the polymer scaffold. However, very little is currently known about the structural effects of polydopamine incorporation during the electropolymerisation of hybrid films. In this work, we combine electrochemical quartz crystal microbalance studies, fundamental electrochemical characterisation, atomic force microscopy, and a suite of spectroscopic techniques in order to correlate changes in the structure and performance of polypyrrole–polydopamine films to the structural modifications of the nanostructure induced by polydopamine incorporation. The results indicate that polydopamine incorporation greatly increases the rate of hybrid film deposition, as well as improving adhesion, surface homogeneity, and wettability, with no compromise in charge transfer properties. Polydopamine incorporation is strongly suggested to occur in non-connected domains within a predominantly polypyrrole-like scaffold. We propose a two-step model of co-polymerisation and the subsequent surface adhesion of hybrid films. Results are expected to be of broad general interest to researchers utilizing polypyrrole and polydopamine to prepare tailor-made electrodes for biosensing and catalysis.
多多巴胺掺杂对电沉积聚吡咯薄膜的纳米结构和电化学性能的影响
聚吡咯薄膜通常被制备成导电电极表面,用于多种应用领域。最近,人们越来越关注通过在聚合物支架中加入生物启发聚多巴胺来改善聚吡咯电极的粘合性能和生物相容性。然而,目前人们对混合薄膜电聚合过程中加入多巴胺的结构影响知之甚少。在这项工作中,我们结合了电化学石英晶体微天平研究、基本电化学表征、原子力显微镜和一系列光谱技术,以便将聚吡咯-聚多巴胺薄膜的结构和性能变化与加入聚多巴胺引起的纳米结构改变联系起来。结果表明,聚多巴胺的加入大大提高了混合薄膜的沉积速率,并改善了附着力、表面均匀性和润湿性,同时电荷转移性能也没有受到影响。我们强烈建议多聚多巴胺的掺入发生在以聚吡咯为主的支架内的非连接域中。我们提出了共聚和随后混合薄膜表面粘附的两步模型。研究结果有望引起利用聚吡咯和聚多巴胺制备用于生物传感和催化的定制电极的研究人员的广泛兴趣。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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