Electrolyte engineering and material modification for graphite‐based lithium‐ion batteries operated at low temperature

Yin, Yue; Dong, Xiaoli

doi:10.1002/idm2.12105

Cited by 13 publications

(4 citation statements)

References 126 publications

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“…It is expected to favour a high fraction of anion‐derived inorganic components in the interphases [22] . We also observe the participation of the SN additive in Na + ‐solvation as suggested by the distinct shift to a higher wavenumber for the SN Raman band upon adding SN into the electrolyte (Supplementary Figure S1b) [12a,23] . The participation of oxidation‐stable SN molecules in Na + ‐solvation is expected to inhibit solvents’ decomposition and to increase the high‐voltage electrolyte stability, as discussed below.…”

Section: Resultsmentioning

confidence: 56%

“…We further performed nuclear magnetic resonance (NMR) and Raman spectroscopy studies for insights into the altered electrolyte solvation behaviour by the introduction of EP. First, the 23 Na NMR spectra exhibit a gradual downfield shift as the volume ratio of EP increases from 10 % to 50 %, indicating the participation of EP in solvating Na + (Figure 1d). [20] The finding is further supported by the Raman spectroscopic study.…”

Section: Resultsmentioning

confidence: 99%

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Tuning the Electrolyte and Interphasial Chemistry for All‐Climate Sodium‐ion Batteries

He,

Zhu,

et al. 2024

Angewandte Chemie

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Sodium‐ion batteries (SIBs) present a promising avenue for next‐generation grid‐scale energy storage. However, realizing all‐climate SIBs operating across a wide temperature range remains a challenge due to the poor electrolyte conductivity and instable electrode interphases at extreme temperatures. Here, we propose a comprehensively balanced electrolyte by pairing carbonates with a low‐freezing‐point and low‐polarity ethyl propionate solvent which enhances ion diffusion and Na+‐desolvation kinetics at sub‐zero temperatures. Furthermore, the electrolyte leverages a combinatorial borate‐ and nitrile‐based additive strategy to facilitate uniform and inorganic‐rich electrode interphases, ensuring excellent rate performance and cycle stability over a wide temperature range from −45 °C to 60 °C. Notably, the Na||sodium vanadyl phosphate cell delivers a remarkable capacity of 105 mA h g−1 with a high rate of 2 C at −25 °C. In addition, the cells exhibit excellent cycling stability over a wide temperature range, maintaining a high capacity retention of 84.7% over 3,000 cycles at 60 °C and of 95.1% at −25 °C over 500 cycles. This study highlights the critical role of electrolyte and interphase engineering for enabling SIBs that function optimally under diverse and extreme climatic environments.

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Section: Resultsmentioning

confidence: 56%

Section: Resultsmentioning

confidence: 99%

Tuning the Electrolyte and Interphasial Chemistry for All‐Climate Sodium‐ion Batteries

He,

Zhu,

et al. 2024

Angewandte Chemie

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“…In addition, previous reports have demonstrated that the EC forms an organic-rich SEI, which results in an increase in interphase impedance . On the other hand, if the EC gets oxidized at a high voltage of >4.4 V (vs Li + /Li) irreversibly, lithium cobalt oxide (LCO) can only provide a specific capacity of less than 150 mAh g –1 with the cutoff voltage of 4.3 V. − Furthermore, during the deep delithiation of LCO at a high voltage, with the assistance of the EC-based electrolytes, the dissolved Co 4+ further facilitates the side reaction of the electrolyte on the surface of the electrode, giving rise to the thick cathode electrolyte interphase (CEI) and high impedance as well. − Therefore, it is necessary to improve the slow lithium-ion intercalation kinetics and the electrochemical window through the electrolyte design. − …”

Section: Introductionmentioning

confidence: 99%

Weakened Solvation Structure Electrolytes Enable High-Voltage Graphite||LiCoO₂ Batteries

You,

Jiang,

Chen

et al. 2024

ACS Appl. Energy Mater.

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In traditional electrolytes, due to the difference of donor number, the cyclic ethylene carbonate (EC) is usually used as the carrier of Li + , while the linear carbonate is used as the cosolvent. However, the poor desolvation ability of EC also leads to poor rate performance. Herein, we reversed the roles of carbonates, where the linear ethyl methyl carbonate (EMC) served as the Li + carrier and the cyclic 3,3,3-trifluoropropylene carbonate (TFPC) acted as the cosolvent. This strategy helped significantly decrease the solvation effect while meeting the need for good solid electrolyte interphase (SEI) growth. Fluorobenzene (FB) was also introduced due to its low viscosity and high electrochemical stability. This electrolyte with a weakly solvated structure greatly improved the rate performance of electrodes. Moreover, the fluorine-rich interface introduced by the design effectively inhibited the dissolution of Co 4+ in the high-voltage LiCoO 2 (LCO) cathode. The LCO delivered a specific capacity of 177 mAh g −1 and a good cycle life with a high cutoff voltage of 4.6 V. A commercial high-voltage graphite||LCO pouch cell using this electrolyte showed a good capacity retention of 99.1% over 100 cycles and a high energy density of 285 Wh kg −1 at 0.3 C (counted by the mass of the whole battery) when charged to 4.5 V.

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“…[14] Despite the above advantages, the large radius of K + (1.38 Å) hampers its insertion into electrode materials and induces significant volume changes during electrochemical reactions, incurring cracking or pulverization of electrode materials. [15][16][17] Various anode materials, such as carbonaceous materials, [18][19][20] metal alloys, [21][22][23] metal oxides, [24,25] and metal sulfides, [26][27][28][29] have been extensively studied. Among them, transition metal sulfides are attractive candidates due to their high theoretical specific capacity, low electronegativity, unique crystal structure, and good redox activity.…”

mentioning

confidence: 99%

SnS₂ nanoparticles embedded in sulfurized polyacrylonitrile composite fibers for high‐performance potassium‐ion batteries

Li,

Tong,

Jiang

et al. 2024

Interdisciplinary Materials

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Potassium‐ion batteries (PIBs) have garnered significant attention as a promising alternative to commercial lithium‐ion batteries (LIBs) due to abundant and cost‐efficient potassium reserves. However, the large size of potassium ions and the resulting sluggish reaction kinetics present major obstacles to the widespread use of PIBs. Herein, we present a simple method to ingeniously encapsulate SnS2 nanoparticles within sulfurized polyacrylonitrile (SPAN) fibers (SnS2@SPAN) for serving as a high‐performance PIB anode. The large interlayer spacing of SnS2 provides a fast transport channel for potassium ions during charge–discharge cycles, while the one‐dimensional SPAN skeleton offers massive binding sites and shortens the diffusion path for potassium ions, facilitating faster reaction kinetics. Additionally, the excellent ductility of SPAN can effectively accommodate the large volume changes that occur in SnS2 upon potassium‐ion insertion, thereby enhancing the cyclic stability of SnS2. Benefiting from the above advantages, the SnS2@SPAN composites exhibit impressive cyclability over 500 cycles at 4 A g−1, with a capacity retention rate close to 100%. This study provides an effective approach for stabilizing high‐capacity PIB anode materials with large volume variations.

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Electrolyte engineering and material modification for graphite‐based lithium‐ion batteries operated at low temperature

Cited by 13 publications

References 126 publications

Tuning the Electrolyte and Interphasial Chemistry for All‐Climate Sodium‐ion Batteries

Tuning the Electrolyte and Interphasial Chemistry for All‐Climate Sodium‐ion Batteries

Weakened Solvation Structure Electrolytes Enable High-Voltage Graphite||LiCoO₂ Batteries

SnS₂ nanoparticles embedded in sulfurized polyacrylonitrile composite fibers for high‐performance potassium‐ion batteries

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Electrolyte engineering and material modification for graphite‐based lithium‐ion batteries operated at low temperature

Cited by 13 publications

References 126 publications

Tuning the Electrolyte and Interphasial Chemistry for All‐Climate Sodium‐ion Batteries

Tuning the Electrolyte and Interphasial Chemistry for All‐Climate Sodium‐ion Batteries

Weakened Solvation Structure Electrolytes Enable High-Voltage Graphite||LiCoO2 Batteries

SnS2 nanoparticles embedded in sulfurized polyacrylonitrile composite fibers for high‐performance potassium‐ion batteries

Contact Info

Product

Resources

About

Weakened Solvation Structure Electrolytes Enable High-Voltage Graphite||LiCoO₂ Batteries

SnS₂ nanoparticles embedded in sulfurized polyacrylonitrile composite fibers for high‐performance potassium‐ion batteries