Ion States Impact Charge Transport and Dielectric Constant for Poly(ethylene oxide)-Based Sulfonylimide Lithium Ionomers

Mei, Wenwen; Yu, Deyang; Madsen, Louis A.; Hickey, Robert J.; Colby, Ralph H.

doi:10.1021/acs.macromol.3c00294

Macromolecules

2023

DOI: 10.1021/acs.macromol.3c00294

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Ion States Impact Charge Transport and Dielectric Constant for Poly(ethylene oxide)-Based Sulfonylimide Lithium Ionomers

Wenwen Mei

Deyang Yu

Louis A. Madsen

et al.

Abstract: Understanding dielectric response and charge transport in ion-containing polymers is essential for the design and implementation of these materials in energy-related applications. Our previous study identified the significant impacts of anion chemical composition on ion conduction for poly(ethylene oxide)-based lithium ionomers with polymer-fixed sulfonylimide (MTLi) and sulfonate anions (J. Mater. Chem. C, 2022, 10, 14569). In this study, we further explore the dielectric response and Li+ conduction in the c… Show more

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Cited by 4 publications

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References 102 publications

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“…In impedance studies, when the frequency of the applied AC potential is low, ions are blocked at the electrode/electrolyte interface and cause electrode polarization. Increasing the distance between electrodes shifts electrode polarization to even lower frequencies. − Figure b shows a lab-built cell used to measure the conductivity of the suspensions. The electrodes are separated by 2.2 cm, and the cell constant is calibrated to be 19.5 cm –1 .…”

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Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Yu,

Tronstad,

McCloskey

2024

ACS Energy Lett.

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Understanding Li + transport in organic−inorganic hybrid electrolytes, where Li + has to lose its organic solvation shell to enter and transport through the inorganic phase, is crucial to the design of high-performance batteries. As a model system, we investigate a range of Li + -conducting particles suspended in a concentrated electrolyte. We show that large Li 1.3 Al 0.3 Ti 1.7 P 3 O 12 and Li 6 PS 5 Cl particles can enhance the overall conductivity of the electrolyte. When studying impedance using a cell with a large cell constant, the Nyquist plot shows two semicircles: a high-frequency semicircle related to ion transport in the bulk of both phases and a medium-frequency semicircle attributed to Li + transporting through the particle/liquid interfaces. Contrary to the high-frequency resistance, the medium-frequency resistance increases with particle content and shows a higher activation energy. Furthermore, we show that small particles, requiring Li + to overcome particle/liquid interfaces more frequently, are less effective in facilitating Li + transport. Overall, this study provides a straightforward approach to study the Li + transport behavior in hybrid electrolytes.

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confidence: 99%

Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Yu,

Tronstad,

McCloskey

2024

ACS Energy Lett.

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Reactive Solid Polymer Layer: From a Single Fluoropolymer to Divergent Fluorinated Interface

Ma,

Guo,

Wen

et al. 2024

Angewandte Chemie

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Controlling the structure and chemistry of solid electrolyte interphase (SEI) underpins the stability of electrolyte‐electrode interface, and is crucial for advancing rechargeable lithium metal batteries (LMBs). Here, we utilized photo‐controlled copolymerization to achieve the on‐demand synthesis of fluorosulfonyl fluoropolymers as unprecedented artificial SEI layers on Li metal anodes. This work not only enables instant formation of a hybrid polymer‐inorganic interphase that consists of a polymer‐enriched top layer and a LiF‐fortified bottom layer, originating from a single polymeric component, but also imparts various desirable physical properties (e.g., good mechanical strength and flexibility, high ion conductivity, low overpotential) to SEI via a single‐to‐divergent strategy. Model reactions and structural characterizations supported the formation of a divergent fluorinated interphase, which furnished prolonged stabilization of Li deposition, high coulombic efficiency and improved cycling behavior in electrochemical experiments. This work highlights the great potential of exploring reactive polymers as versatile coatings to stabilize Li metal anodes, providing a promising avenue to solve electrode‐electrolyte interfacial problems for LMBs.

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Reactive Solid Polymer Layer: From a Single Fluoropolymer to Divergent Fluorinated Interface

Ma,

Guo,

Wen

et al. 2024

Angew Chem Int Ed

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Ion States Impact Charge Transport and Dielectric Constant for Poly(ethylene oxide)-Based Sulfonylimide Lithium Ionomers

Cited by 4 publications

References 102 publications

Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Lithium-Ion Transport and Exchange between Phases in a Concentrated Liquid Electrolyte Containing Lithium-Ion-Conducting Inorganic Particles

Reactive Solid Polymer Layer: From a Single Fluoropolymer to Divergent Fluorinated Interface

Reactive Solid Polymer Layer: From a Single Fluoropolymer to Divergent Fluorinated Interface

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