Advanced Electrolytes for Fast‐Charging High‐Voltage Lithium‐Ion Batteries in Wide‐Temperature Range

Zhang, Xianhui; Zou, Lianfeng; Xu, Yaobin; Cao, Xia; Engelhard, Mark H.; Matthews, Bethany E.; Zhong, Lirong; Wu, Haiping; Jia, Hao; Ren, Xiaodi; Gao, Peiyuan; Chen, Zonghai; Qin, Yan; Kompella, Christopher; Arey, Bruce W.; Li, Jun; Wang, Deyu; Wang, Chongmin; Zhang, Ji‐Guang; Xu, Wu

doi:10.1002/aenm.202000368

Cited by 178 publications

(173 citation statements)

References 37 publications

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“…29,30 Considering the high cost and viscosity of SCE, diluting SCE with non-polar solvents emerged in recent years as an alternative to mitigate these issues. [31][32][33] The diluted SCE is termed localized superconcentrated electrolytes (LSCE) because the local solvation structure of LSCE is very similar to that of SCE, and therefore they belong to the same methodology.…”

mentioning

confidence: 99%

Regulating Interfacial Chemistry in Lithium‐Ion Batteries by a Weakly Solvating Electrolyte**

et al. 2020

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The performance of lithium-ion battery is highly dependent on its interfacial chemistry, which is regulated by electrolytes. Conventional electrolyte typically contains polar solvents to dissociate Li salts. Here, we report a novel weakly-solvating electrolyte (WSE) that consists of a pure non-polar solvent, which leads to a peculiar solvation structure where ion pairs and aggregates prevail under a low salt concentration of 1.0 M. Importantly, WSE forms unique anion-derived interphases on graphite electrodes that exhibit fast-charging and long-term cycling characteristics. First-principles calculations unravel a general principle that the competitive coordination between anions and solvents to Li ion is the origin of different interfacial chemistries. By bridging the gap between solution thermodynamics and interfacial chemistry in batteries, this work opens a brand-new way towards precise electrolyte engineering for energy storage devices with desired properties.

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mentioning

confidence: 99%

Regulating Interfacial Chemistry in Lithium‐Ion Batteries by a Weakly Solvating Electrolyte**

et al. 2020

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“…For example, Zhang et al showed that at low temperatures (‐20 and −30 °C), Gr/NCA cells deliver higher capacity with a LiBF 4 electrolyte than with a LiPF 6 counterpart while the LiBF 4 electrolyte has lower ionic conductivity. Similarly, Yamada et al demonstrated that a Li/Gr cell with 3.6 M LiFSI‐DME electrolyte having a lower ionic conductivity (7.2 mS cm −1 ) outperforms that with 1.0 M LiPF 6 ‐EC‐DMC electrolyte (∼10 mS cm −1 ); Zhang et al reported that at 5 C, a Gr/NMC811 cell with 2.8 mAh cm −2 of NMC811 loading demonstrates higher capacity with a 1.4 m LiFSI DMC‐EC‐TTE electrolyte (2:0.2 : 3 by mol, 1.07 mS cm −1 ) than with a 1.0 m LiPF 6 EC‐EMC electrolyte (3 : 7 by wt+2 wt% VC, 6.07 mS cm −1 ). The above results reveal that the ionic conductivity of the electrolytes is not the only factor governing the fast‐charging capability.…”

Section: Challenges and Strategiesmentioning

confidence: 96%

Challenges and Strategies for Fast Charge of Li‐Ion Batteries

Zhang

2020

ChemElectroChem

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Long charging time for Li‐ion batteries is a critical obstacle for the widespread adoption of electric vehicles, especially when compared with the rapid refueling of traditional internal combustion engine vehicles. Fast charging results in accelerated performance degradation and low energy efficiency for Li‐ion batteries. The batteries adopted in the present electric vehicle market are mainly based on chemistry consisting of a graphite anode and a layered lithium transition‐metal oxide cathode. The fast‐charging capability of such batteries is limited by Li plating on the graphite anode and structural instability of the layered lithium transition‐metal oxide cathode. In this Minireview, the challenges and possible solutions to these fast charge problems are reviewed at both the materials and cell levels.

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“…For the mixture of solvents, cyclic ethylene carbonate (EC) is considered to be an indispensable co-solvent for the formation of robust solid-electrolyte-interphase (SEI) on the graphite anode, and the other solvent can be a linear dimethyl carbonate (DMC), diethyl carbonate (DEC), ethylmethyl carbonate (EMC), or their mixture for reduced viscosity and low freezing temperature of the electrolytes. In some cases, small amounts of esters [7][8][9] or ethers 10,11 that have a low boiling point and acceptably chemical stability are added to enable operations at low temperatures or/and high current rates. However, such benefits often come with a trade-off in reversibility and lifetime.…”

Section: Current Statusmentioning

confidence: 99%

“…Therefore, the solutions to the first question should be centered on the second and third steps as shown in Figure 1. While fast charge necessitates high ionic conductivity, several studies revealed that some electrolytes with LiBF 4 26,27 and LiFSI 11,28 have lower conductivity, however, the resultant batteries exhibit higher capacity and lower polarization at low temperatures and high rates compared with those using the conventional LiPF 6 ‐carbonate electrolytes. Although the mechanism for the above phenomena is yet unclear, these findings point out a fact that the ionic conductivity of the electrolytes is not the only factor governing the fast‐charging capability.…”

Section: Future Needs and Prospectsmentioning

confidence: 99%

Design aspects of electrolytes for fast charge of Li‐ion batteries

Zhang

2020

InfoMat

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The electrolytes of Li-ion batteries consist mainly of a LiPF 6 salt dissolved in a carbonate-based solvent mixture. Such electrolytes cannot support fast charge without detrimental impacts on performance and lifetime. Fast charge aggravates parasitic reactions of the electrolyte solvents and structural degradation of the lithium layered transition metal oxide cathode materials. This leads to not only the depletion of electrolyte solvents but also the loss of cyclable Li + ions, accompanied by impedance growth and volumetric swelling of the battery. In this perspective, the design aspects of the electrolytes for fast charge of Li-ion batteries are discussed and proposed.

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Advanced Electrolytes for Fast‐Charging High‐Voltage Lithium‐Ion Batteries in Wide‐Temperature Range

Cited by 178 publications

References 37 publications

Regulating Interfacial Chemistry in Lithium‐Ion Batteries by a Weakly Solvating Electrolyte**

Regulating Interfacial Chemistry in Lithium‐Ion Batteries by a Weakly Solvating Electrolyte**

Challenges and Strategies for Fast Charge of Li‐Ion Batteries

Design aspects of electrolytes for fast charge of Li‐ion batteries

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