Interfacial Effects in Conductivity Measurements of Block Copolymer Electrolytes

IF 4.7 Q1 POLYMER SCIENCE
Jonathan P. Coote, Samuel K. J. Adotey, Joshua R. Sangoro and Gila E. Stein*, 
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引用次数: 1

Abstract

The ionic conductivity in lamellar block copolymer electrolytes is often anisotropic, where the in-plane conductivity exceeds the through-plane conductivity by up to an order of magnitude. In a prior work, we showed significant anisotropy in the ionic conductivity of a lamellar block copolymer based on polystyrene (PS) and a polymer ionic liquid (PIL), and we proposed that the through-film ionic conductivity was depressed by layering of lamellar domains near the electrode surface. In the present work, we first tested that conclusion by measuring the through-plane ionic conductivity of two model PIL-based systems having controlled interfacial profiles using impedance spectroscopy. The measurements were not sensitive to changes in interfacial composition or structure, so anisotropy in the ionic conductivity of PS-block-PIL materials must arise from an in-plane enhancement rather than a through-plane depression. We then examined the origin of this in-plane enhancement with a series of PS-block-PIL materials, a P(S-r-IL) copolymer, and a PIL homopolymer, where impedance spectra were acquired with a top-contact electrode configuration. These studies show that enhanced in-plane ionic conductivities are correlated with the formation of an IL-rich wetting layer at the free surface, which presumably provides a low-resistance path for ion transport between the electrodes. Importantly, the enhanced in-plane ionic conductivities in these PS-block-PIL materials are consistent with simple geometric arguments based on properties of the PIL, while the through-plane values are an order of magnitude lower. Consequently, it is critical to understand how surface and bulk effects contribute to impedance spectroscopy measurements when developing structure–conductivity relations in this class of materials.

Abstract Image

嵌段共聚物电解质电导率测量中的界面效应
层状嵌段共聚物电解质中的离子导电性通常是各向异性的,其中平面内导电性超过穿过平面的导电性高达一个数量级。在先前的工作中,我们展示了基于聚苯乙烯(PS)和聚合物离子液体(PIL)的层状嵌段共聚物的离子电导率的显著各向异性,并且我们提出通过在电极表面附近分层层状畴来降低通膜离子电导率。在目前的工作中,我们首先通过使用阻抗谱测量具有受控界面轮廓的两个基于PIL的模型系统的过平面离子电导率来测试这一结论。测量结果对界面组成或结构的变化不敏感,因此PS嵌段PIL材料的离子电导率的各向异性必须来自平面内增强而不是平面内凹陷。然后,我们用一系列PS嵌段PIL材料、P(S-r-IL)共聚物和PIL均聚物研究了这种面内增强的起源,其中用顶部接触电极配置获得了阻抗谱。这些研究表明,增强的面内离子电导率与在自由表面形成富含IL的润湿层有关,这可能为电极之间的离子传输提供了低电阻路径。重要的是,这些PS嵌段PIL材料中增强的平面内离子电导率与基于PIL性质的简单几何参数一致,而通平面值低一个数量级。因此,在开发这类材料的结构-导电关系时,了解表面和体积效应如何对阻抗谱测量做出贡献至关重要。
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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CiteScore
2.50
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