Impact of Nano- and Mesoscales on Macroscopic Cation Conductivity in Perfluorinated-Sulfonic-Acid Membranes

Crothers, Andrew R.; Radke, Clayton J.; Weber, Adam Z.

doi:10.1021/acs.jpcc.7b07360

Cited by 27 publications

(28 citation statements)

References 74 publications

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“…Hydrophilic domain spacing, ordering, and connectivity are important parameters related to phase separation that determine transport pathways. These morphology features need to be understood to construct relationships between molecular structure and ion conductivity . SAXS can reveal the degree of phase separation in ionomer membranes.…”

Section: Results and Discussionmentioning

confidence: 99%

“…This suggests subtle chemistry differences could play a role in nanoswelling of domains and overall conductivity. Modeling and simulation studies have shown that electrostatic interactions within polymer-bound anionic groups and cation solvation energy have the greatest impact on charge migration at the molecular and domain scale, and this is influenced by the chemistry and resulting charge delocalization on the side-chain. , Previous work has shown that the proximity of protogenic groups and the charge delocalization on the side-chain are important factors that dictate hydrogen bonding and proton dissociation at low hydration levels . PFICE ionomers have a side-chain chemistry and combination of protogenic groups that facilitates water hydrogen-bonding configurations promoting proton dissociation, as illustrated in Figure .…”

Section: Results and Discussionmentioning

confidence: 99%

“…These morphology features need to be understood to construct relationships between molecular structure and ion conductivity. 74 SAXS can reveal the degree of phase separation in ionomer membranes. Because ionomers, and many similar charge-containing polymers in general, are relatively disordered, the peaks in SAXS tend to be broad without higher-order peaks visible, indicating only short-range order in these materials.…”

Section: Journal Of the American Chemical Societymentioning

confidence: 99%

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Chemical and Morphological Origins of Improved Ion Conductivity in Perfluoro Ionene Chain Extended Ionomers

Cordova

Yandrasits

et al. 2019

J. Am. Chem. Soc.

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The performance of ion-conducting polymer membranes is complicated by an intricate interplay between chemistry and morphology that is challenging to understand.Here, we report on perfuoro-ionene chain extended (PFICE) ionomers that contain either one or two bis(sulfonyl)imide groups on the side-chain in addition to a terminal sulfonic acid group. PFICE ionomers exhibit greater water uptake and conductivity compared to prototypical perfluorinated sulfonic acid ionomers. Advanced in situ synchrotron characterization reveals insights into the connections between molecular structure and morphology that dictate performance. Guided by first-principles 1 calculations, X-ray absorption spectroscopy at the sulfur K-edge can discern distinct protogenic groups and be sensitive to hydration level and configurations that dictate proton dissociation. In situ resonant X-ray scattering at the sulfur K-edge reveals that PFICE ionomers have a phase-separated morphology with enhanced short-range order that persists in both dry and hydrated states. The enhanced conductivity of PFICE ionomers is attributed to a unique multi-acid side-chain chemistry and structure that facilitates proton dissociation at low water content in combination with a well-ordered phase-separated morphology with nanoscale transport pathways. Overall, these results provide insights for the design of new ionomers with tunable phase-separation and improved transport properties and demonstrate the efficacy of X-rays with elemental sensitivity for unraveling structural features in chemically-heterogeneous functional materials for electrochemical energy applications.

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Section: Results and Discussionmentioning

confidence: 99%

Section: Results and Discussionmentioning

confidence: 99%

Section: Journal Of the American Chemical Societymentioning

confidence: 99%

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Chemical and Morphological Origins of Improved Ion Conductivity in Perfluoro Ionene Chain Extended Ionomers

Cordova

Yandrasits

et al. 2019

J. Am. Chem. Soc.

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“…The change in the slope of conductivity against hydration was previously reported for proton-form PFSAs, and associated with the ion exchange capacity and more recently modeled to be related to mesoscale network tortuosity. 6,60 Conductivity of an interconnected water domainnetwork as a function of the domain volume fraction is expressed as:…”

Section: 3mentioning

confidence: 99%

Morphology and Transport of Multivalent Cation-Exchanged Ionomer Membranes Using Perfluorosulfonic Acid–Ce^Z+ as a Model System

Baker

Crothers

Chintam

et al. 2020

ACS Appl. Polym. Mater.

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Perfluorosulfonic acids (PFSAs), are commonly used as solid polymer electrolyte membranes (PEMs) in electrochemical energy devices, where they are vulnerable to attack by hydroxyl radical species during operation, which reduces their effectiveness. A popular strategy to combat this problem is to introduce radical scavengers like cerium (Ce) ions that neutralize these species before they attack the PFSA. Such cation doping creates a multi-ion system, in which understanding the mechanisms of cation solvation and transport becomes important for effective design and utilization of PFSA-cation systems. Ce ions also provide a representative model system for multication-exchanged ionomers in electrochemical systems. In this study, hydration and conductivity measurements, along with X-ray fluorescence and scattering, are employed to elucidate how Ce ion exchange alters PFSA's ionic solvation as well as nano-and mesoscale morphology which ultimately control its ion transport properties. A molecular transport model is used to delineate the impact of Ce ions on the local solvation structure of water in the membrane from mesoscale changes of the transport pathways. The combined experimental and theoretical analysis reveals a nonlinear decrease in conductivity driven by cation solvation at the molecular level and morphological changes at larger length scales. Migration-diffusion coupling, its nonlinear dependence on ion-exchange and hydration, and its overall implications for ionomer performance are also discussed in order to provide an applicable case study. These findings have the potential to be translated into other mixed cation-ionomer systems for a wide range of energy and environmental devices.

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“…In recent years, nano-confined structures have been exploited in the study of cost-effective and reliable polymer architectures for electrochemical devices [ 29 , 30 , 31 , 32 , 33 , 34 , 35 , 36 , 37 ]. Understanding the water structure and the behavior of ions in these confined structures is essential to gain insight into the ion diffusion mechanisms.…”

Section: Introductionmentioning

confidence: 99%

OH− and H3O+ Diffusion in Model AEMs and PEMs at Low Hydration: Insights from Ab Initio Molecular Dynamics

Zelovich

Tuckerman

2021

Membranes

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Fuel cell-based anion-exchange membranes (AEMs) and proton exchange membranes (PEMs) are considered to have great potential as cost-effective, clean energy conversion devices. However, a fundamental atomistic understanding of the hydroxide and hydronium diffusion mechanisms in the AEM and PEM environment is an ongoing challenge. In this work, we aim to identify the fundamental atomistic steps governing hydroxide and hydronium transport phenomena. The motivation of this work lies in the fact that elucidating the key design differences between the hydroxide and hydronium diffusion mechanisms will play an important role in the discovery and determination of key design principles for the synthesis of new membrane materials with high ion conductivity for use in emerging fuel cell technologies. To this end, ab initio molecular dynamics simulations are presented to explore hydroxide and hydronium ion solvation complexes and diffusion mechanisms in the model AEM and PEM systems at low hydration in confined environments. We find that hydroxide diffusion in AEMs is mostly vehicular, while hydronium diffusion in model PEMs is structural. Furthermore, we find that the region between each pair of cations in AEMs creates a bottleneck for hydroxide diffusion, leading to a suppression of diffusivity, while the anions in PEMs become active participants in the hydronium diffusion, suggesting that the presence of the anions in model PEMs could potentially promote hydronium diffusion.

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Impact of Nano- and Mesoscales on Macroscopic Cation Conductivity in Perfluorinated-Sulfonic-Acid Membranes

Cited by 27 publications

References 74 publications

Chemical and Morphological Origins of Improved Ion Conductivity in Perfluoro Ionene Chain Extended Ionomers

Chemical and Morphological Origins of Improved Ion Conductivity in Perfluoro Ionene Chain Extended Ionomers

Morphology and Transport of Multivalent Cation-Exchanged Ionomer Membranes Using Perfluorosulfonic Acid–Ce^Z+ as a Model System

OH− and H3O+ Diffusion in Model AEMs and PEMs at Low Hydration: Insights from Ab Initio Molecular Dynamics

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Impact of Nano- and Mesoscales on Macroscopic Cation Conductivity in Perfluorinated-Sulfonic-Acid Membranes

Cited by 27 publications

References 74 publications

Chemical and Morphological Origins of Improved Ion Conductivity in Perfluoro Ionene Chain Extended Ionomers

Chemical and Morphological Origins of Improved Ion Conductivity in Perfluoro Ionene Chain Extended Ionomers

Morphology and Transport of Multivalent Cation-Exchanged Ionomer Membranes Using Perfluorosulfonic Acid–CeZ+ as a Model System

OH− and H3O+ Diffusion in Model AEMs and PEMs at Low Hydration: Insights from Ab Initio Molecular Dynamics

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Product

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Morphology and Transport of Multivalent Cation-Exchanged Ionomer Membranes Using Perfluorosulfonic Acid–Ce^Z+ as a Model System