Highly conductive divalent fluorosulfonyl imide based electrolytes improving Li-ion battery performance: Additive potentiating electrolytes action

Imide-based electrolyte salts are crucial in lithium-ion battery (LIB) research, due to their high oxidative capacity, thermal performance, and cycling stability. LIBs with imide electrolytes exhibit slow charge-discharge (CD) capacity and high efficiency, even though most of these electrolytes show...

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Bibliographic Details
Published in:Journal of power sources 2020-04, Vol.455, p.227980, Article 227980
Main Authors: Ahmed, Faiz, Choi, Inhwan, Ryu, Taewook, Yoon, Sujin, Rahman, Md Mahabubur, Zhang, Wei, Jang, Hohyoun, Kim, Whangi
Format: Article
Language:English
Subjects:
Additive
Anodic stability
Imide electrolyte
Lithium-ion battery
Specific capacity
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Summary:Imide-based electrolyte salts are crucial in lithium-ion battery (LIB) research, due to their high oxidative capacity, thermal performance, and cycling stability. LIBs with imide electrolytes exhibit slow charge-discharge (CD) capacity and high efficiency, even though most of these electrolytes show low ionic conductivity (σ). Herein, we have synthesized two highly conductive and pure divalent imide electrolytes, lithium sulfonylbis(fluorosulfonyl)imide (LiSFSI) and lithium (1,3-phenylenedisulfonyl)bis(fluoro sulfonyl)imide (LiPDSFSI), for LIBs application. Compared to LiPDSFSI electrolyte, the LiSFSI imide electrolyte with mixed solvent ethylene carbonate (EC) and dimethyl sulfoxide (DMSO) (75:25 v/v) exhibits better electrochemical stability, σ, transference number (tL+), cycling stability, and high specific capacity of 142 mAhg−1 with the full cell battery configuration of LiFePO4/electrolytes/graphite at 0.1 C. Additionally, lithium bis(fluoro-sulfonyl)imide (LiFSI) (20%), as additive, improve their performance substantially. The results demonstrate that the LiSFSI electrolyte with LiFSI additive shows maximum σ (8.9 mS/cm at 30 °C), tLi+ (0.64), and anodic stability (5.47 V), which concurrently delivers high efficiency and improves specific capacity to 156 mAhg−1 with excellent capacity retention (99.93%) after 500 CD cycles with the full cell LiFePO4/electrolytes/graphite battery system. [Display omitted] •LiSFSI and LiPDSFSI ionic salts were synthesized to prepare an electrolyte for LIB.•Both electrolytes showed excellent electrochemical performance in LIB.•LIB performance of these electrolytes was enhanced by adding LiFSI additive.•The LiSFSI electrolyte with LiFSI additive delivered a maximum Csp of 160 mAhg−1 at 0.1 C.
ISSN:0378-7753
1873-2755
DOI:10.1016/j.jpowsour.2020.227980