Structure–Conductivity Relationships of Block Copolymer Membranes Based on Hydrated Protic Polymerized Ionic Liquids: Effect of Domain Spacing

Structure–Conductivity Relationships of Block Copolymer Membranes Based on Hydrated Protic Polymerized Ionic Liquids: Effect of Domain Spacing

Elucidating the relationship between chemical structure, morphology, and ionic conductivity is essential for designing novel high-performance materials for electrochemical applications. In this work, the effect of lamellar domain spacing (d) on ionic conductivity (σ) is investigated for a model syst...

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Bibliographic Details
Published in:Macromolecules Vol. 49; no. 6; pp. 2216 - 2223
Main Authors: Sanoja, Gabriel E, Popere, Bhooshan C, Beckingham, Bryan S, Evans, Christopher M, Lynd, Nathaniel A, Segalman, Rachel A
Format: Journal Article
Language:English
Published: American Chemical Society 22-03-2016
Online Access:Get full text
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Summary:Elucidating the relationship between chemical structure, morphology, and ionic conductivity is essential for designing novel high-performance materials for electrochemical applications. In this work, the effect of lamellar domain spacing (d) on ionic conductivity (σ) is investigated for a model system of hydrated diblock copolymer based on a protic polymerized ionic liquid. We present a strategy that allows for the synthesis of a well-defined series of narrowly dispersed PS-b-PIL with constant volume fraction of ionic liquid moieties (f IL ≈ 0.39) and with two types of mobile charge carriers: trifluoroacetate anions and protons. These materials self-assemble into ordered lamellar morphologies with variable domain spacing (ca. 20–70 nm) as demonstrated by small-angle X-ray scattering. PS-b-PIL membranes exhibit ionic conductivities above 10–4 S/cm at room temperature, which are independent of domain spacing consistent with their nearly identical water content. The conductivity scaling relationship demonstrated in this paper suggests that a mechanically robust membrane can be designed without compromising its ability to transport ions. In addition, PIL-based membranes exhibit low water uptake (λ ≈ 10) in comparison with many proton-conducting systems reported elsewhere. The low water content of the materials described herein makes them promising candidates for electrochemical devices operating in aqueous electrolytes at low current densities where moderate ion conduction and low product crossover are required.
ISSN:0024-9297
1520-5835
DOI:10.1021/acs.macromol.5b02614