Temperature-Responsive Solvation of Deep Eutectic Electrolyte Enabling Mesocarbon Microbead Anode for High-Temperature Li-Ion Batteries

Hou, Qian; Li, Peiwen; Qi, Yaqin; Wang, Yueda; Huang, Minghao; Shen, Chao; Xiang, Hongfa; Li, Nan; Xie, Keyu

doi:10.1021/acsenergylett.3c01079

Cited by 26 publications

(5 citation statements)

References 42 publications

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“…Further, the deconvolution of C≡N bands in the electrolyte solutions of SN-FEC and DEC-SN-FEC shows an additional peak at 2264 cm −1 (green peak), indicating the participation of SN in Na + solvation by C≡N•••Na + coordination. [27,28] The observation is further supported by 23 Na NMR spectroscopy (Figure 1i). The downfield shift (more positive) of the 23 Na chemical shift in SN-FEC compared to the EC-PC electrolyte implies weaker solvation for Na + by SN molecules.…”

Section: Electrolyte Solvation Structurementioning

confidence: 54%

Electrolyte Engineering with Tamed Electrode Interphases for High‐Voltage Sodium‐Ion Batteries

Liu,

Zhu,

Wang

et al. 2024

Advanced Materials

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Sodium‐ion batteries (SIBs) hold great promise for next‐generation grid‐scale energy storage. However, the highly instable electrolyte/electrode interphases threat long‐term cycling of high‐energy SIBs. In particular, the instable cathode electrolyte interphase (CEI) at high voltage causes persistent electrolyte decomposition, transition metal dissolution and fast capacity fade. Here we propose a balanced principle for molecular design of SIB electrolytes that enable an ultra‐thin, homogeneous and robust CEI layer by coupling an intrinsically oxidation stable succinonitrile solvent with moderately solvating carbonates. The proposed electrolyte not only shows limited anodic decomposition thus leading to a thin CEI, but also suppresses dissolution of CEI components at high voltage. Consequently, the tamed electrolyte/electrode interphases enable extremely stable cycling of Na3V2O2(PO4)2F (NVOPF) cathodes with outstanding capacity retention (> 90%) over 3000 cycles (eight months) at 1 C with a high charging voltage of 4.3 V. Further, the NVOPF||hard carbon full cell shows stable cycling over 500 cycles at 1 C with a high average Coulombic efficiency of 99.6%. The electrolyte also endows high‐voltage operation of SIBs with great temperature adaptability from −25 oC to 60 °C, shedding light on the essence of fundamental electrolyte design for SIBs operating under harsh conditions.This article is protected by copyright. All rights reserved

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Section: Electrolyte Solvation Structurementioning

confidence: 54%

Electrolyte Engineering with Tamed Electrode Interphases for High‐Voltage Sodium‐Ion Batteries

Liu,

Zhu,

Wang

et al. 2024

Advanced Materials

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“…Figure comprehensively illustrates the “arched-window” structured design for constructing novel eutectic electrolytes, where extensive attention is paid to the relationship among anion categories and Lewis base choice, eutectic thermodynamic and model construction, eutectic electrolyte–interphase chemistry, and liquid preservation ability at low temperatures. This figure provides a favorable prospect for the grid-scale implementation of metal-ion storage devices. , The change of solvation structure and SEI under sub-zero temperature is beneficial to deepen the understanding of the eutectic interactions and illuminate the eutectics’ future . Moreover, the electrolyte must simultaneously cooperate with all other battery components (cathode, anode, current collector, and separator).…”

Section: Eutectic Electrolytes Driving Low-temperature Mibsmentioning

confidence: 99%

Eutectic Electrolytes Convoying Low-Temperature Metal-Ion Batteries

Qu,

Lu,

Jiang

et al. 2024

ACS Energy Lett.

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Eutectic electrolytes have been widely used in low-temperature metal-ion batteries (MIBs) due to their good performance regardless of seasonal and regional changes. Durable low-temperature MIBs rely on the constitution, proportion, and solvation-structure construction of eutectic electrolytes to maintain high ionic conductivity and electrochemical stability. Despite the rapid advances in eutectic electrolytes, some key issues, including fundamental mechanisms, theoretical models, aqueous/non-aqueous controversies, and challenges at sub-zero temperatures, need to be addressed. This Review first gives an overview of eutectic chemistry by presenting fundamental analysis and proposing new models to demonstrate the variety of interactions and anti-freezing mechanisms. Then, the thermodynamics and mass transfer, Helmholtz electric double-layer configuration, and electrode–electrolyte interphase are discussed to uncover the influence of the eutectic structure on the electrochemistry of low-temperature MIBs. Finally, a summary and perspectives are provided to guide the design principles and requirements of eutectic systems for applications of MIBs in low-temperature scenarios.

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“…25–28 Moreover, the variation of the temperatures can induce the corresponding changes in the coordination interaction of Li + with solvents and anions, leading to the transformation of the primary solvation structure of Li + . 29–32 The interaction between the electrolyte and the SEI becomes even more complex because the SEI formation process is closely linked to the reduction stability of the solvated components, especially when thermal reduction interferes at elevated temperature. 13,33 This highlights the significant effect of temperature on the solvation sheath and SEI film.…”

Section: Introductionmentioning

confidence: 99%

Unraveling the temperature-responsive solvation structure and interfacial chemistry for graphite anodes

Mo,

Liu,

Chen

et al. 2024

Energy Environ. Sci.

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Temperature-Responsive Solvation of Deep Eutectic Electrolyte Enabling Mesocarbon Microbead Anode for High-Temperature Li-Ion Batteries

Cited by 26 publications

References 42 publications

Electrolyte Engineering with Tamed Electrode Interphases for High‐Voltage Sodium‐Ion Batteries

Electrolyte Engineering with Tamed Electrode Interphases for High‐Voltage Sodium‐Ion Batteries

Eutectic Electrolytes Convoying Low-Temperature Metal-Ion Batteries

Unraveling the temperature-responsive solvation structure and interfacial chemistry for graphite anodes

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