Role of Filler Content and Morphology in LLZO/PEO Membranes

Din, Mir Mehraj Ud; Häusler, Michael; Fischer, Susanne M.; Ratzenböck, Karin; Chamasemani, Fereshteh Falah; Hanghofer, Isabel; Henninge, V; Brunner, Roland; Slugovc, Christian; Rettenwander, Daniel

doi:10.3389/fenrg.2021.711610

Cited by 15 publications

(16 citation statements)

References 40 publications

(50 reference statements)

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“…Figure a shows the conductivity of 0 wt % LLZO and 50 wt % LLZO composite electrolytes at various temperatures. At all temperatures, the electrolytes with 50 wt % nanofibers have lower conductivity than PEO-LiTFSI alone; this is in line with previous reports demonstrating a maximum plasticizing effect of ceramic content around 10–20 wt % before a drop in conductivity is seen. , Below 30 °C, there are slight deviations in conductivity and activation energy trends between 0 and 50 wt % LLZO. These differences may be related to the Li + and TFSI – transport along the fiber surface or PEO plasticization, both of which can be impacted by the fiber surface’s Lewis acidity or basicity. − Above 30 °C, all samples exhibit the same activation energies, indicating that the polymer phase dominates ion transport at the temperatures used in our cycling.…”

Section: Results and Discussionsupporting

confidence: 91%

Understanding the Influence of Li₇La₃Zr₂O₁₂ Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes

Counihan,

Powers,

Barai

et al. 2023

ACS Appl. Mater. Interfaces

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Composite polymer electrolytes (CPEs) are attractive materials for solid-state lithium metal batteries, owing to their high ionic conductivity from ceramic ionic conductors and flexibility from polymer components. As with all lithium metal batteries, however, CPEs face the challenge of dendrite formation and propagation. Not only does this lower the critical current density (CCD) before cell shorting, but the uncontrolled growth of lithium deposits may limit Coulombic efficiency (CE) by creating dead lithium. Here, we present a fundamental study on how the ceramic components of CPEs influence these characteristics. CPE membranes based on poly(ethylene oxide) and lithium bis(trifluoromethanesulfonyl)imide (PEO-LiTFSI) with Li7La3Zr2O12 (LLZO) nanofibers were fabricated with industrially relevant roll-to-roll manufacturing techniques. Galvanostatic cycling with lithium symmetric cells shows that the CCD can be tripled by including 50 wt % LLZO, but half-cell cycling reveals that this comes at the cost of CE. Varying the LLZO loading shows that even a small amount of LLZO drastically lowers the CE, from 88% at 0 wt % LLZO to 77% at just 2 wt % LLZO. Mesoscale modeling reveals that the increase in CCD cannot be explained by an increase in the macroscopic or microscopic stiffness of the electrolyte; only the microstructure of the LLZO nanofibers in the PEO-LiTFSI matrix slows dendrite growth by presenting physical barriers that the dendrites must push or grow around. This tortuous lithium growth mechanism around the LLZO is corroborated with mass spectrometry imaging. This work highlights important elements to consider in the design of CPEs for high-efficiency lithium metal batteries.

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Section: Results and Discussionsupporting

confidence: 91%

Understanding the Influence of Li₇La₃Zr₂O₁₂ Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes

Counihan,

Powers,

Barai

et al. 2023

ACS Appl. Mater. Interfaces

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“…The Li‐ion transport in this system is mainly attributed to the amorphous polymer. Additionally, the cause of the lower ionic conductivity of composite than LLZO ceramic seems to be an extension in the conduction pathway with the formation of an interfacial barrier 158 . The ionic conductivity of NZSP ceramic powder is higher than the NZSP‐doped PVDF–HFP powder studied by Kim et al 148 .…”

Section: Ceramic and Polymer Composite Electrolytesmentioning

confidence: 89%

“…Additionally, the cause of the lower ionic conductivity of composite than LLZO ceramic seems to be an extension in the conduction pathway with the formation of an interfacial barrier. 158 The ionic conductivity of NZSP ceramic powder is higher than the NZSP-doped PVDF-HFP powder studied by Kim et al 148 In this case, the active filler allows more Na-ion transport than polymer; accordingly, the polymerceramic interfacial layer function as a high-energy barrier to conducting Na-ions. Another example of polymer in ceramic-type composite electrolyte NZSP/PEO was studied by Wang et al and a decrease in ionic conduction from 1.4 × 10 −4 to .83 × 10 −4 S/cm was observed with an increased volume fraction from 10% to 25% of polymer filler in the ceramic matrix.…”

Section: Polymer-ceramic Interfacementioning

confidence: 92%

Overview and perspectives of solid electrolytes for sodium batteries

Vasudevan

Dwivedi

Balaya

2022

Int J Applied Ceramic Tech

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Quoting the abundance and cost of sodium reserve and robustly safe and high-energy solid electrolytes, sodium solid-state batteries (SSBs) exhibit huge promise for future energy storage applications compared to battery systems using organic liquid electrolytes and Li counterparts. However, the progress and application are still in infancy, experiencing numerous challenges for sodium SSBs due to inherent properties, interface complications, and fabrication. These are recently receiving unprecedented research attention by understanding and steadily resolving the issues associated with sodium SSBs. In this review, the governing bulk and interfacial issues and dynamics, background research correlations from Li counterparts, and strategies to address them are investigated for various ceramic-, polymer-, and ceramic-polymer composite based solid electrolytes. Particular attention is devoted to issues with ceramic electrolytes (such as interfacial stability, brittleness, porosity, and grain-grain boundary resistance) and polymer electrolytes (like dendrite formation, passivation layer, electrochemical instability, and ionic conductivity), and finally, robustness in overall performance and a few drawbacks (such as filler agglomeration, interface dynamics, and crack propagation) on the composited state-of-the-art ceramicpolymer electrolytes are highlighted. To end with, crucial inferences and future research perspectives are condensed on the development of enhanced solid electrolytes for sodium SSBs overcoming the shortcomings illustrated for different electrolytes.

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“…Thus, numerous efforts are made by researchers to improve Li ionic conductivity of LLZO SSE (Lv et al, 2021). Some of these efforts are made by forming composites (Huang et al, 2019;Li et al, 2019), designing specialised morphology (Wu et al, 2020;Din et al, 2021;Kravchyk et al, 2022) and by changing method of synthesis (Sakamoto et al, 2013;Yang et al, 2020). Among these, doping remains one of the major efforts (Adhyatma et al, 2022;Wang et al, 2022).…”

Section: Lithium Lanthanum Zirconatementioning

confidence: 99%

Materials Towards the Development of Li Rechargeable Thin Film Battery

Singh

2023

Prabha Materials Science Letters

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The present work gives an overview of materials towards the development of Li rechargeable thin film batteries. Conventional Li rechargeable battery faces issues related with large volume, safety issues due to the presence of liquid electrolyte. These issues are proposed to resolve by developing these batteries in thin film form. The main drawback of these batteries is finding an appropriate inorganic material to be used as electrolytes. Other issue is related with design of appropriate cathode material which should be cost effective and is able to provide better electrochemical performance compared to competitive counterparts. In this review, a brief description of lithium lanthanum zirconate as a solid-state electrolyte and Co free Ni rich layered oxide has been provided to overcome these issues. Strategies for optimizing these materials for designing a stable, safe and cost-effective thin film batteries are also elaborated.

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Role of Filler Content and Morphology in LLZO/PEO Membranes

Cited by 15 publications

References 40 publications

Understanding the Influence of Li₇La₃Zr₂O₁₂ Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes

Understanding the Influence of Li₇La₃Zr₂O₁₂ Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes

Overview and perspectives of solid electrolytes for sodium batteries

Materials Towards the Development of Li Rechargeable Thin Film Battery

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Role of Filler Content and Morphology in LLZO/PEO Membranes

Cited by 15 publications

References 40 publications

Understanding the Influence of Li7La3Zr2O12 Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes

Understanding the Influence of Li7La3Zr2O12 Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes

Overview and perspectives of solid electrolytes for sodium batteries

Materials Towards the Development of Li Rechargeable Thin Film Battery

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Product

Resources

About

Understanding the Influence of Li₇La₃Zr₂O₁₂ Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes

Understanding the Influence of Li₇La₃Zr₂O₁₂ Nanofibers on Critical Current Density and Coulombic Efficiency in Composite Polymer Electrolytes