Polymeric ionic liquid-functionalized mesoporous silica nanoplates: a new high-performance composite polymer electrolyte for lithium batteries

[Display omitted] •Desirable ion-conducting channels are created by introduction of PIL-FMSiNP in CPE.•PIL/IL(LiTFSI)/PIL-FMSiNP CPE shows high ionic conductivity.•PIL-FMSiNP effectively improves the electrochemical stability and interfacial stability.•Cell with PIL/IL(LiTFSI)/PIL-FMSiNP CPE exhibit...

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Bibliographic Details
Published in:Electrochimica acta 2017-08, Vol.245, p.1010-1022
Main Authors: Wang, Shun, Shi, Qing Xuan, Ye, Yun Sheng, Wang, Yong, Peng, Hai Yan, Xue, Zhi Gang, Xie, Xiao Lin, Mai, Yiu Wing
Format: Article
Language:English
Subjects:
Batteries
Carrier density
Composite polymer electrolyte
Current carriers
Electrodes
Electrolytes
Electrolytic cells
Interface stability
Ion currents
Ionic liquid
Ionic liquids
Ionic mobility
Lithium batteries
Mesoporous structure
Nanocomposites
Polymeric ionic liquid
Polymers
Silica nanoplates
Silicon dioxide
Studies
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Summary:[Display omitted] •Desirable ion-conducting channels are created by introduction of PIL-FMSiNP in CPE.•PIL/IL(LiTFSI)/PIL-FMSiNP CPE shows high ionic conductivity.•PIL-FMSiNP effectively improves the electrochemical stability and interfacial stability.•Cell with PIL/IL(LiTFSI)/PIL-FMSiNP CPE exhibits remarkably improved discharged capacities and cyclabilities. A composite polymer electrolyte based on an ionic liquid, Li salt and polymeric ionic liquid that included PIL-functionalized mesoporous silica nanoplates is prepared through a simple solution-casting method. A PIL-functionalized mesoporous silica content (8wt.%) optimized composite polymer electrolyte possesses high ionic conductivity, a high Li ion transference number, and good interfacial stability characteristics superior to those of a plain PIL-based electrolyte or incorporating PIL-functionalized silica nanoplates. The incorporation of porous structured silica nanoplates leads to the creation of a continuous and interconnected conductive network, and weakens the anionic and cationic interactions of the IL and Li salts, thereby improving ionic mobility and charge carrier concentration. Also, the PIL-functionalized mesoporous silica nanoplates effectively improves the electrochemical stability and interfacial stability of the polymer electrolyte with the Li metal electrode and anode electrode, due to its large surface area and the high affinity resulting from porous structures and grafted PIL. Accordingly, Li/LiFePO4 cells with composite polymer electrolyte and PIL-functionalized mesoporous silica nanoplates exhibit remarkably improved discharged capacities and cyclabilities, compared to cells with plain PIL-based polymer electrolyte,displaying a higher average specific capacities at 40 and 60°C, approximating to 228% and 152% enhancements after 100 cycles, respectively.
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2017.05.125