Enthalpic and Entropic Contributions to Fast Lithium Ion Conduction in Solid-State Aqueous Polymer Electrolytes

Park, Jae Hyun; Jung, Sungyeb; Handayani, Puji Lestari; Aluru, N. R.; Kim, Taehoon; Lee, Sang Bok; Choi, U Hyeok; Lee, Jaekwang

doi:10.1021/acs.jpcc.2c03513

Cited by 3 publications

(3 citation statements)

References 32 publications

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“…In addition, after normalizing inverse temperature by the extrapolated σ relaxation temperature T σ , defined at ω σ ( T σ ) = 10 –2 rad/s (Figure d), all the conduction frequency ω σ data of these electrolytes merge into a single VFT curve (see the inset of Figure d). Therefore, this indicates that the lithium cations, bound to the carboxylate (COO – ) groups in PLiA, are released from the polymer chains by hydration to form conducting ions, migrate along the water channel formed by phase separation, and then are again trapped by other PLiA chains . These releasing and trapping processes are the main hopping mechanism of ion transport and are closely related to the ion-exchanging α 2 process.…”

Section: Resultsmentioning

confidence: 99%

“…Therefore, this indicates that the lithium cations, bound to the carboxylate (COO − ) groups in PLiA, are released from the polymer chains by hydration to form conducting ions, migrate along the water channel formed by phase separation, and then are again trapped by other PLiA chains. 40 These releasing and trapping processes are the main hopping mechanism of ion transport and are closely related to the ion-exchanging α 2 process.…”

Section: Hpe Relaxation Processmentioning

confidence: 99%

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Ionic Conduction and Dielectric Response of Nanoparticle-Coupled Hydrogel Network Polymer Electrolytes

et al. 2023

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The molecular level understanding of ion and polymer dynamics in nanoparticle-coupled hydrogel network polymer electrolytes is investigated by linear dielectric and viscoelastic measurements covering broad ranges of frequency and temperature. We prepare hydrogel polymer electrolytes (HPEs), composed of Li + conducting hydrophilic poly(lithium acrylate) (PLiA) as the HPE matrix and vinyl-functionalized silica nanoparticles (NPs) as cross-linking points, via radical polymerization and sol−gel reaction. The NP content variation leads to changes in ionic conductivity (σ DC ), dielectric constant (ε s ), relaxation frequency, and elastic modulus, which are important characteristic factors for understanding ion transport. From the physical model of electrode polarization (EP), allowing for the determination of the number density of simultaneously conducting ions and their mobility, the NP-containing HPEs (HPE-NP) have simultaneously higher conducting ion concentration (p) and mobility (μ), resulting in higher ionic conductivity (σ DC ∼ pμ), compared to the HPE without NPs. The temperature dependence of p and μ follows Arrhenius (thermally activated) and Vogel−Fulcher (segmentally driven) temperature dependences, respectively. In addition to the lower frequency EP, the HPEs show higher frequency relaxation (α 2 ), attributed to ions rearranging. NP incorporation leads to faster α 2 relaxation and higher static dielectric constant ε s (shorter Bjerrum length l B ). Time−temperature superposition (tTS) works well for these electrolytes and is applied to construct master curves of viscoelasticity and in-phase conductivity. In the end, the NP-containing HPE-based supercapacitor is fabricated using carbon nanotube yarn (CNTY) electrodes and shows stable electrochemical performance, demonstrating that our HPE can be a solid-state polymer electrolyte for energy storage devices.

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Section: Resultsmentioning

confidence: 99%

Section: Hpe Relaxation Processmentioning

confidence: 99%

Ionic Conduction and Dielectric Response of Nanoparticle-Coupled Hydrogel Network Polymer Electrolytes

et al. 2023

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“…While significant progress has been made in understanding ion transport mechanisms in the extremes of dry polymeric electrolytes and highly swollen polymer membranes, these fields have generally been developed independently, leading to knowledge gaps regarding transport in low- to moderately hydrated polymer systems. Recently, significant interest has arisen in such a regime for energy storage applications. − For example, aqueous solid polymer electrolytes (polymer and water-in-salt electrolytes) exhibit high ionic conductivities, preferential lithium transport, and improved safety compared to solid polymer electrolytes, as well as improved electrochemical stability compared to salt-in-water electrolytes . The ability to control ion permeation and ionic conductivity in low to moderately hydrated polymer systems hinges on developing fundamental insights into the interplay between ion–ion, ion–polymer, and ion–water interactions and the role of ion-polymer solvation on ion transport in the transition between “dry” and “hydrated” polymer systems.…”

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Ion and Water Dynamics in the Transition from Dry to Wet Conditions in Salt-Doped PEG

Marioni,

Nordness,

Zhang

et al. 2024

ACS Macro Lett.

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The influence of the water content on ion and water transport mechanisms in polymer membranes under low to moderate hydration conditions remains poorly understood. In this study, we combine ion and water diffusivity (PFG-NMR) measurements with atomistic molecular dynamics simulations to better understand transport processes in hydrated salt-doped poly(ethylene glycol). Above the water percolation threshold, the experimental and simulated diffusivities are in good agreement with the free volume transport models. At low hydration levels, unlike dry systems, ion diffusion cannot be described by polymer segmental dynamics alone. We rationalize such observations by the interplay between ion−water and ion−polymer solvation of cations and between ion−water and cation−anion interactions for anions. Further, we demonstrate that a two-state model combining ion−water solvation and free volume transport can describe water dynamics across the entire hydration range of interest. Our findings provide a more encompassing analysis of ion and water transport in hydrated polyelectrolytes, specifically in the low hydration regime.

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Exceptionally flexible and stable quasi-solid-state supercapacitors via salt-in-polyampholytes electrolyte with non-freezable properties

Min Park,

Hyeok Choi

2024

Chemical Engineering Journal

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Enthalpic and Entropic Contributions to Fast Lithium Ion Conduction in Solid-State Aqueous Polymer Electrolytes

Cited by 3 publications

References 32 publications

Ionic Conduction and Dielectric Response of Nanoparticle-Coupled Hydrogel Network Polymer Electrolytes

Ionic Conduction and Dielectric Response of Nanoparticle-Coupled Hydrogel Network Polymer Electrolytes

Ion and Water Dynamics in the Transition from Dry to Wet Conditions in Salt-Doped PEG

Exceptionally flexible and stable quasi-solid-state supercapacitors via salt-in-polyampholytes electrolyte with non-freezable properties

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