Enabling the Li-ion conductivity of Li-metal fluorosulphates by ionic liquid grafting

Barpanda, Prabeer; Dedryvère, Rémi; Deschamps, Michaël; Delacourt, Charles; Reynaud, Marine; Yamada, Atsuo; Tarascon, Jean‐Marie

doi:10.1007/s10008-011-1598-y

Cited by 17 publications

(15 citation statements)

References 17 publications

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“…Smaller particles lead to a shortened diffusion path for Li + and to better electrode kinetics in agreement with our experimental results. Another possibility to account for such a difference could be the presence of an EMI-TFSI grafting layer at the surface of LiFeSO 4 F which will enhance the ionic conductivity, as previously reported for LiZnSO 4 F. 12 This would contrast with an ionic blocking thin layer of TTEG at the surface of LiFeSO 4 F made in glycol-based media, although such a possibility is therefore quite unlikely given that repeatedly washing the sample yielded no changes in performance.…”

Section: Electrochemical Performancementioning

confidence: 92%

Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO₄F electrodes for Li-ion batteries

et al. 2015

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Material abundance and eco--efficient synthetic protocols are becoming the overriding factors for developing sustainable Li--ion batteries, hence today's great interest in LiFePO4. The recently reported tavorite--type LiFeSO4F cathode material, which shows a redox potential of 3.6 V and a practical capacity of 130 mAh g --1 without the need for sophisticated carbon coating or particle downsizing, stands presently as a serious contender to LiFePO4. However, its synthesis is still not routinely reproducible. Herein, we offer a direct explanation by showing the strong effect of the room temperature relative humidity on both LiFeSO4F aging stability and electrochemical performances. We demonstrate the complete degradation of tavorite--type LiFeSO4F into FeSO4·•nH2O (n = 1, 4, 7) and LiF in environments with relative humidities greater than 62%, and also show the feasibility of triggering in situ formation of a F ----free (Li)FeSO4OH phase within the cell. This work, which we also extend to the 3.9 V triplite--type LiFeSO4F polymorph, provides a foundation for achieving the consistent production and handling of LiFeSO4F electrodes in view of large--scale manufacturing. This moisture sensitivity issue, which can be mitigated by surface treatments, is inherent to sulfate--based electrode materials and the battery community must be aware of it.

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Section: Electrochemical Performancementioning

confidence: 92%

Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO₄F electrodes for Li-ion batteries

et al. 2015

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“…For a while, Barpanda and coworkers sustained their effort towards understanding the underlying mechanism of such increment in ionic conductivity for the IL-assisted synthesized LiZnSO 4 F. The presence of a thin layer of IL attached to the LiZnSO 4 F surface resulted in the formation of a slightly Li-rich ceramic IL composite claimed to contribute to the improvement in conductivity. [60] With the intention of attesting the flexibility of the ILgrafting-induced conductivity enhancement and its crystalstructure-independent nature, this phenomenon was extended to other non-isostructural Li-metal fluorosulfate family members such as LiMSO 4 F (M = Co, Mn). Thus, the IL grafting can be utilized as an alternative process for the synthesis of ceramic-IL composites endowed with much higher ionic conductivity, very close to the benchmarking range needed for solid electrolyte applications.…”

Section: Ceramic Electrolytesmentioning

confidence: 99%

Energy Storage Materials Synthesized from Ionic Liquids

et al. 2014

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The advent of ionic liquids (ILs) as eco-friendly and promising reaction media has opened new frontiers in the field of electrochemical energy storage. Beyond their use as electrolyte components in batteries and supercapacitors, ILs have unique properties that make them suitable as functional advanced materials, media for materials production, and components for preparing highly engineered functional products. Aiming at offering an in-depth review on the newly emerging IL-based green synthesis processes of energy storage materials, this Review provides an overview of the role of ILs in the synthesis of materials for batteries, supercapacitors, and green electrode processing. It is expected that this Review will assess the status quo of the research field and thereby stimulate new thoughts and ideas on the emerging challenges and opportunities of IL-based syntheses of energy materials.

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“…When the LiMSO 4 F materials are prepared using ionic‐liquid media, a thin layer of ionic liquid is permanently attached to the grain boundaries (Figure 4d). An XPS and solid‐state NMR spectroscopy study proves the presence of the 8–15 nm thick ionic‐liquid graft (IG) 23b. This offers excellent Li + permeability to form a percolating network for Li + migration, although the bulk of the material is not so conducting.…”

Section: Fluorosulfatesmentioning

confidence: 98%

Sulfate Chemistry for High‐Voltage Insertion Materials: Synthetic, Structural and Electrochemical Insights

Barpanda

2015

Israel Journal of Chemistry

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Rechargeable batteries based on Li and Na ions have been growing leaps and bounds since their inception in the 1970s. They enjoy significant attention from both the fundamental science point of view and practical applications ranging from portable electronics to hybrid vehicles and grid storage. The steady demand for building better batteries calls for discovery, optimisation and implementation of novel positive insertion (cathode) materials. In this quest, chemists have tried to unravel many future cathode materials by taking into consideration their eco‐friendly synthesis, material/process economy, high energy density, safety, easy handling and sustainability. Interestingly, sulfate‐based cathodes offer a good combination of sustainable syntheses and high energy density owing to their high‐voltage operation, stemming from electronegative SO42− units. This review delivers a sneak peak at the recent advances in the discovery and development of sulfate‐containing cathode materials by focusing on their synthesis, crystal structure and electrochemical performance. Several family of cathodes are independently discussed. They are 1) fluorosulfates [AMSO4F], 2) bihydrated fluorosulfates [AMSO4F ⋅ 2H2O], 3) hydroxysulfate [AMSO4OH], 4) bisulfates [A2M(SO4)2], 5) hydrated bisulfates [A2M(SO4)2 ⋅ nH2O], 6) oxysulfates [Fe2(SO4)2O] and 7) polysulfates [A2M2(SO4)3]. A comparative study of these sulfate‐based cathodes has been provided to offer an outlook on the future development of high‐voltage polyanionic cathode materials for next‐generation batteries.

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Enabling the Li-ion conductivity of Li-metal fluorosulphates by ionic liquid grafting

Cited by 17 publications

References 17 publications

Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO₄F electrodes for Li-ion batteries

Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO₄F electrodes for Li-ion batteries

Energy Storage Materials Synthesized from Ionic Liquids

Sulfate Chemistry for High‐Voltage Insertion Materials: Synthetic, Structural and Electrochemical Insights

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Enabling the Li-ion conductivity of Li-metal fluorosulphates by ionic liquid grafting

Cited by 17 publications

References 17 publications

Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO4F electrodes for Li-ion batteries

Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO4F electrodes for Li-ion batteries

Energy Storage Materials Synthesized from Ionic Liquids

Sulfate Chemistry for High‐Voltage Insertion Materials: Synthetic, Structural and Electrochemical Insights

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Product

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Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO₄F electrodes for Li-ion batteries

Influence of relative humidity on the structure and electrochemical performance of sustainable LiFeSO₄F electrodes for Li-ion batteries