Lithium Difluorophosphate as a Widely Applicable Additive to Boost Lithium‐Ion Batteries: a Perspective

Wang, Aiping; Wang, Li; Liang, Hong; Song, Yaqin; He, Yufang; Wu, Yanzhou; Ren, Dongsheng; Zhang, Bo; He, Xiangming

doi:10.1002/adfm.202211958

Cited by 12 publications

(5 citation statements)

References 57 publications

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“…The electrolytes were prepared by dissolving 2 M lithium bis(trifluoromethanesulfonyl)imide (LiFSI) in a mixture of DX and EGDBE (1 : 1 in volume), and 0.15 M lithium difluorophosphate (LiDFP) additive was used further to improve the high voltage property of batteries. [23] The resulting electrolyte was designated as DX + EGDBE. For reference, the same concentration of LiFSI and LiDFP salts was dissolved in a mixture of DOL and DME (1 : 1 in volume) or a mixture of EC and DEC (1 : 1 in volume), and the obtained electrolytes were designated as DOL + DME and EC + DEC, respectively.…”

Section: Resultsmentioning

confidence: 99%

Non‐Fluorinated Ethers to Mitigate Electrode Surface Reactivity in High‐Voltage NCM811‐Li Batteries

Wang,

Che,

Wang

et al. 2024

Angewandte Chemie

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Lithium (Li) metal batteries (LMBs) with nickel (Ni)‐rich layered oxide cathodes exhibit twice the energy density of conventional Li‐ion batteries. However, their lifespan is limited by severe side reactions caused by high electrode reactivity. Fluorinated solvent‐based electrolytes can address this challenge, but they pose environmental and biological hazards. This work reports on the molecular engineering of fluorine (F)‐free ethers to mitigate electrode surface reactivity in high‐voltage Ni‐rich LMBs. By merely extending the alkyl chains of traditional ethers, we effectively reduce the catalytic reactivity of the cathode towards the electrolyte at high voltages, which suppresses the oxidation decomposition of the electrolyte, microstructural defects and rock‐salt phase formation in the cathode, and gas release issues. The high‐voltage Ni‐rich NCM811‐Li battery delivers capacity retention of 80% after 250 cycles with a high Coulombic efficiency of 99.85%, even superior to that in carbonate electrolytes. Additionally, this strategy facilitates passivation of the Li anode by forming a robust solid‐electrolyte interphase, boosting the Li reversibility to 99.11% with a cycling life of 350 cycles, which outperforms conventional F‐free ether electrolytes. Consequently, the lifespan of practical LMBs has been prolonged by over 100% and 500% compared to those in conventional carbonate‐ and ether‐based electrolytes, respectively.

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Section: Resultsmentioning

confidence: 99%

Non‐Fluorinated Ethers to Mitigate Electrode Surface Reactivity in High‐Voltage NCM811‐Li Batteries

Wang,

Che,

Wang

et al. 2024

Angewandte Chemie

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“…Apart from the commonly used carbonate and ether solvents, phosphates [110,111] , sulfonamide [112] , sulfones [113][114][115][116] , and nitriles [117][118][119][120][121][122][123][124] were also evaluated as promising solvents to suppress the anodic Al dissolution. In 2020, Zheng et 5A], for use in LIBs [110] .…”

Section: Optimization Of Solventmentioning

confidence: 99%

Strategies towards inhibition of aluminum current collector corrosion in lithium batteries

Han,

Chen,

et al. 2023

Energy Mater

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Aluminum (Al) foil, serving as the predominant current collector for cathode materials in lithium batteries, is still unsatisfactory in meeting the increasing energy density demand of rechargeable energy storage systems due to its severe corrosion under high voltages. Such Al corrosion may cause delamination of cathodes, increasement of internal resistance, and catalysis of electrolyte decomposition, thus leading to premature failure of batteries. Hence, a systematic understanding of the corrosion mechanisms and effective anticorrosion strategies are necessary to enhance overall performance of lithium batteries. In this review, the corrosive mechanisms related to Al current collectors are systematically summarized and clarified. In addition, an overview on recent progress and advancement of strategies toward inhibiting Al corrosion is presented. In the end, we also provide a perspective with motivation to stimulate new ideas and research directions to further inhibit Al corrosion to achieve high energy density, long cycle life, and high safety of lithium batteries.

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“…Developing new Ni-rich cathodes (LiNi 1‑ x ‑ y ‑ z Mn x Co y Al z O 2 ) and enhancing the upper charge cutoff voltage are considered as the direct way to boost the energy density of LIBs. , Many researches have been done on the structure design for a typical ternary cathode material of LiNi x Co y Mn 1‑ x ‑ y O 2 . , Among these key elements, as the Ni content increases, higher discharge capacity will be obtained, whereas the cation mixture degree increases and the corresponding discharge capacity is reduced if more Co elements are implanted. , Furthermore, the price of cobalt is greatly influenced by the supply chain in the past decade, which limits the availability of cobalt and hinders the growth of the EV market. Instead, Co-free and Ni-rich high-voltage materials are considered as the most promising cathode due to the high specific capacity, low cost, and environment-friendliness. − However, the practical applications of the Co-free high voltage cathode are greatly inhibited by the poor cathode–electrolyte interface (CEI) layer formed on the cathode surface in the carbonated electrolytes containing LiPF 6 salt, especially at voltages higher than 4.4 V. The poor oxidation stability of the carbonate-based electrolyte leads to continuous interfacial side reactions that suppress the Li + migration and increase the cell polarization. , Meantime, the oxygen revolution, fatigue of secondary particles, formation of intergranular crack, and dissolution of transition metal ion that occur at high-voltage conditions further cause the capacity decay and early death of the cell, especially at high operating voltages and elevated temperatures. − …”

Section: Introductionmentioning

confidence: 99%

Electrolyte Regulation in Stabilizing the Interface of a Cobalt-Free Layered Cathode for 4.8 V High-Voltage Lithium-Ion Batteries

Ma,

Zhu,

Yang

et al. 2024

ACS Appl. Mater. Interfaces

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The cobalt-free layered oxide cathode of Li-Ni 0.65 Mn 0.35 O 2 is promising for high-energy-density lithium-ion batteries (LIBs). However, under high-voltage conditions, severe side reactions between the Co-free cathode and electrolyte, as well as grain boundary cracks and pulverization of particles, hinder its practical applications. Herein, an electrolyte regulation strategy is proposed by adding fluoroethylene carbonate (FEC) and LiPO 2 F 2 as electrolyte additives in carbonate-based electrolytes to address the above issues. As a result, a homogeneous and dense organic−inorganic hybrid cathode electrolyte interface (CEI) film is formed on the cathode surface. The CEI film consists of C-F, LiF, Li 2 CO 3 , and Li x PO y F z species, which is proven to be highly conductive and effective in suppressing structure damage and alleviating the interfacial reactions between the cathode and electrolyte. With such a CEI film, the interfacial stability of the Co-free cathode and the high-voltage cycling performance of Li||LiNi 0.65 Mn 0.35 O 2 are greatly improved. A reversible capacity of 155.1 mAh g −1 and a capacity retention of 81.3% over 150 cycles are attained at a 4.8 V charge cutoff voltage with the tamed electrolyte, whereas the cell without the additives only retains 76.1% capacity retention. Therefore, our work demonstrates the synergistic effect of FEC and LiPO 2 F 2 in stabilizing the interface of Co-free cathode materials and provides an alternative strategy for the electrolyte design of high-voltage LIBs.

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Lithium Difluorophosphate as a Widely Applicable Additive to Boost Lithium‐Ion Batteries: a Perspective

Cited by 12 publications

References 57 publications

Non‐Fluorinated Ethers to Mitigate Electrode Surface Reactivity in High‐Voltage NCM811‐Li Batteries

Non‐Fluorinated Ethers to Mitigate Electrode Surface Reactivity in High‐Voltage NCM811‐Li Batteries

Strategies towards inhibition of aluminum current collector corrosion in lithium batteries

Electrolyte Regulation in Stabilizing the Interface of a Cobalt-Free Layered Cathode for 4.8 V High-Voltage Lithium-Ion Batteries

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