Comparison of surface density of ferrocene and rate of electron transfer on different ferrocene immobilized ITO electrodes

IF 2.8 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Research on Chemical Intermediates Pub Date : 2025-03-24 DOI:10.1007/s11164-025-05561-0

Takashi Fukushima, Isshi Imai, Hayato Ito, Seito Kimura, Yuichiro Namura, Mai Fujimoto, Soma Kitajima, Kohei Shimada, Wataru Mitsuhashi, Michiru Yoshii, Shinya Higashimoto

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引用次数: 0

Abstract

Immobilization of electro-functional molecules onto the electrode surface often plays an important role in the fabrication of electrochemical devices such as photo-voltaic cells, fuel cells, semiconductors, and sensors. Although some molecular-immobilization techniques have been developed, few studies have explored relationships between the immobilization techniques and the properties of the resulting composite electrodes such as the surface density of the molecules, charge transfer rate between the electrode and molecules. In this study, electroactive Fc molecules were immobilized on an ITO electrode surface by two different immobilization methods, i.e., (1) azido functionalization of the ITO surface with 3-azidopropyltriethoxysilane (N₃-PTES) followed by copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC) with ethynylferrocene (ITO|N₃-PTES|Fc) and (2) azido functionalization of the ITO surface with electro-deposited 2′-azidomethyl-3,4-ethylenedioxythiophene (N₃-EDOT) polymer film followed by CuAAC with ethynylferrocene (ITO|N₃-EDOT|Fc). A characteristic difference in the electrochemical devices fabricated by the two methods was the rate of electron transfer at the immobilized Fc interface. The apparent charge transfer constant on the ITO|N₃-EDOT|Fc was estimated to be 2.8 s⁻¹, while that on the ITO|N₃-PTES|Fc was much faster at 97 s⁻¹. This suggests that molecular immobilization methods such as silane coupling agents, which tend to give monomolecular layer, offer efficient electron transfer compared to electropolymerization, which tends to give random and thick molecular layer. These results suggest that different immobilization methods of ITO substrates can significantly affect the charge transfer efficiency of immobilized Fc, demonstrating that they provide important guidelines for the fabrication of more efficient electrochemical devices.

Graphical abstract

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不同二茂铁固定ITO电极上二茂铁表面密度和电子转移速率的比较

电功能分子在电极表面的固定化在光伏电池、燃料电池、半导体和传感器等电化学器件的制造中起着重要的作用。虽然已经开发了一些分子固定技术，但很少有研究探讨固定技术与所得到的复合电极的性能之间的关系，如分子的表面密度，电极与分子之间的电荷转移速率。本研究通过两种不同的固定方法将电活性Fc分子固定在ITO电极表面，即(1)用3-叠氮丙基三乙基氧基硅烷（N3-PTES）对ITO表面进行叠氮官能化，然后用铜(I)催化叠氮-炔环加成（CuAAC）与乙基二茂铁（ITO|N3-PTES|Fc）；(2)用电沉积2 ' -叠氮甲基-3,4-乙烯二氧噻吩（N3-EDOT）聚合物膜对ITO表面进行叠氮官能化，然后用CuAAC与乙基二茂铁（ITO|N3-EDOT|Fc）。两种方法制备的电化学器件的特征差异在于固定Fc界面上的电子转移速率。ITO|N3-EDOT|Fc上的表观电荷转移常数估计为2.8 s−1，而ITO|N3-PTES|Fc上的表观电荷转移常数要快得多，为97 s−1。这表明分子固定方法，如硅烷偶联剂，倾向于形成单分子层，相比于电聚合，倾向于形成随机和厚的分子层，提供了有效的电子转移。这些结果表明，不同的ITO衬底固定化方法可以显著影响固定化Fc的电荷转移效率，为制造更高效的电化学器件提供了重要的指导。图形抽象

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来源期刊

Research on Chemical Intermediates 化学-化学综合

CiteScore

5.70

自引率

18.20%

发文量

229

审稿时长

2.6 months

期刊介绍： Research on Chemical Intermediates publishes current research articles and concise dynamic reviews on the properties, structures and reactivities of intermediate species in all the various domains of chemistry. The journal also contains articles in related disciplines such as spectroscopy, molecular biology and biochemistry, atmospheric and environmental sciences, catalysis, photochemistry and photophysics. In addition, special issues dedicated to specific topics in the field are regularly published.