High Conductivity in a Fluorine-Free K-Ion Polymer Electrolyte

Elmanzalawy, Mennatalla; Sánchez-Ahijón, Elena; Kisacik, Ozden; Carretero‐González, Javier; Castillo‐Martínez, Elizabeth

doi:10.1021/acsaem.2c01485

Cited by 13 publications

(6 citation statements)

References 43 publications

(89 reference statements)

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“…Notably, this work achieves, for the first time, SPBMs with ultra‐high average coulombic efficiency of 99.94% (Figure 5d; Figure S36a, Supporting Information) stable cycles over 3000 cycles (≈5100 h), and the cell does not fail during the entire test, and this work is the longest cycle of SPMBs at present (Figure S36b, Supporting Information). [ 66,73–79 ] Corresponding cyclic voltammetry tests, cross‐section SEM, and FTIR spectroscopy of the cell demonstrate that ISPE remains electrochemically and structurally stable after a long period of cycling (Figures S37 and S38, Supporting Information). These results indicates that the ISPE has an excellent high voltage resistance and long cycle life.…”

Section: Resultsmentioning

confidence: 99%

Building Stable Solid‐State Potassium Metal Batteries

Lyu,

Yu,

et al. 2024

Advanced Materials

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Solid‐state potassium metal batteries (SPMBs) are promising candidates for the next generation of energy storage systems for their low cost, safety, and high energy density. However, full SPMBs have not yet been reported due to the K dendrites, interfacial incompatibility, and limited availability of suitable solid‐state electrolytes. Here, we present stable SPMBs using a new iodinated solid polymer electrolyte (ISPE). The functional ions reconstruct ion transport channels, providing efficient potassium ion transport. ISPE shows a combination of high ionic conductivity, superior interfacial compatibility, and electrochemical stability. In‐situ alloying and iodinated interlayer increase K metal compatibility for prolonged cycling with low polarization. Moreover, the ISPE enables SPMBs with Prussian blue cathode stable operation at a high voltage of 4.5 V, a superior rate capability, and long‐term cycling over 3,000 cycles (4.2 V versus K+/K) with an ultra‐high coulombic efficiency of 99.94%. More importantly, a classic solid‐state potassium metal pouch cell achieved 4.2 V stable cycling over 800 cycles with an high retention of 93.6%, presenting a new development strategy for secure and high‐performance rechargeable solid‐state potassium metal batteries.This article is protected by copyright. All rights reserved

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Section: Resultsmentioning

confidence: 99%

Building Stable Solid‐State Potassium Metal Batteries

Lyu,

Yu,

et al. 2024

Advanced Materials

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“…439 Despite the existence of polymer electrolytes exhibiting high K + conductivity, the literature on solid-state potassium-ion conductors remains relatively scarce. 443–476 As a result, the current focus of research revolves around enhancing the ionic conductivity of solid-state potassium-ion conductors. However, it is essential to note that other pivotal electrochemical properties often remain insufficiently characterised, including electrochemical stability, ion selectivity, mechanical properties, and assembly techniques.…”

Section: High-energy-density Potassium-ion Battery Full Cell Designmentioning

confidence: 99%

Advancements in cathode materials for potassium-ion batteries: current landscape, obstacles, and prospects

Masese,

Kanyolo

2024

Energy Adv.

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“…[ 469 ] The (PEO) 30 /KBPh 4 SPEs with Prussian blue electrodes show reversible K + ‐ion de‐/intercalation with a reversible 20 mAh g–1 capacity and lower‐voltage hysteresis. [ 470 ] Rayung et al. [ 471 ] reported polyurethane acrylate‐based SPE due to inspiration of coordination of characteristic of N─H, C═O, and C‐O‐C groups for K + stabilization; however, it limits EW ≈ 2 V. PEO‐based SPEs with K‐salts (such as KCl, KFSI, KBr, CH 3 COOK), polyester‐based ([‐O‐ (C═O) –O‐]) and polyurethane (─[NH─(C═O)─O]n─) SPEs and others (PVP, PVA) have been reported for K + interface kinetics; however, their poor ion‐conductivity (10 −5 –10 −8 S cm −1 ) and operating temperatures, and EWs inhibits the chemical and electrochemical stabilities against K‐metals.…”

Section: Anode Interface Chemistrymentioning

confidence: 99%

Li, Na, K, Mg, Zn, Al, and Ca Anode Interface Chemistries Developed by Solid‐State Electrolytes

Shinde,

Wagh,

Kim

et al. 2023

Advanced Science

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Solid‐state batteries (SSBs) have received significant attention due to their high energy density, reversible cycle life, and safe operations relative to commercial Li‐ion batteries using flammable liquid electrolytes. This review presents the fundamentals, structures, thermodynamics, chemistries, and electrochemical kinetics of desirable solid electrolyte interphase (SEI) required to meet the practical requirements of reversible anodes. Theoretical and experimental insights for metal nucleation, deposition, and stripping for the reversible cycling of metal anodes are provided. Ion transport mechanisms and state‐of‐the‐art solid‐state electrolytes (SEs) are discussed for realizing high‐performance cells. The interface challenges and strategies are also concerned with the integration of SEs, anodes, and cathodes for large‐scale SSBs in terms of physical/chemical contacts, space‐charge layer, interdiffusion, lattice‐mismatch, dendritic growth, chemical reactivity of SEI, current collectors, and thermal instability. The recent innovations for anode interface chemistries developed by SEs are highlighted with monovalent (lithium (Li+), sodium (Na+), potassium (K+)) and multivalent (magnesium (Mg2+), zinc (Zn2+), aluminum (Al3+), calcium (Ca2+)) cation carriers (i.e., lithium‐metal, lithium‐sulfur, sodium‐metal, potassium‐ion, magnesium‐ion, zinc‐metal, aluminum‐ion, and calcium‐ion batteries) compared to those of liquid counterparts.

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High Conductivity in a Fluorine-Free K-Ion Polymer Electrolyte

Cited by 13 publications

References 43 publications

Building Stable Solid‐State Potassium Metal Batteries

Building Stable Solid‐State Potassium Metal Batteries

Advancements in cathode materials for potassium-ion batteries: current landscape, obstacles, and prospects

Li, Na, K, Mg, Zn, Al, and Ca Anode Interface Chemistries Developed by Solid‐State Electrolytes

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