Enhanced electrochemical and mechanical properties of P(VDF-HFP)-based composite polymer electrolytes with SiO2 nanowires

P. Zhang; L. C. Yang; L. L. Li; M. L. Ding; Y. P. Wu; R. Holze

doi:10.1016/j.memsci.2011.05.043

Enhanced electrochemical and mechanical properties of P(VDF-HFP)-based composite polymer electrolytes with SiO₂ nanowires

P. Zhang, L. C. Yang, L. L. Li, M. L. Ding, Y. P. Wu, R. Holze

Research output: Contribution to journal › Article › peer-review

149 Scopus citations

Abstract

Composite polymer electrolytes prepared by adding SiO₂ nanowires into P(VDF-HFP) are described. Their electrochemical and mechanical properties were improved by 3-dimensional network interaction between the nanowires and the polymer chains. The composite polymer membrane can tolerate a maximal stress of 27.8MPa. The ionic conductivity of the prepared gelled polymer electrolyte is up to 1.08×10^-3Scm^-1, the electrochemical window is 4.8V. The composite polymer electrolyte with a 1-dimensional nanofiller such as SiO₂ nanowires provides a new way to polymer electrolytes with better electrochemical and mechanical performance for practical applications in lithium ion batteries.

Original language	English
Pages (from-to)	80-85
Number of pages	6
Journal	Journal of Membrane Science
Volume	379
Issue number	1-2
DOIs	https://doi.org/10.1016/j.memsci.2011.05.043
State	Published - 1 Sep 2011
Externally published	Yes

Keywords

Composite polymer electrolyte
Lithium ion batteries
Nanowires
SiO

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.memsci.2011.05.043

Cite this

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title = "Enhanced electrochemical and mechanical properties of P(VDF-HFP)-based composite polymer electrolytes with SiO2 nanowires",

abstract = "Composite polymer electrolytes prepared by adding SiO2 nanowires into P(VDF-HFP) are described. Their electrochemical and mechanical properties were improved by 3-dimensional network interaction between the nanowires and the polymer chains. The composite polymer membrane can tolerate a maximal stress of 27.8MPa. The ionic conductivity of the prepared gelled polymer electrolyte is up to 1.08×10-3Scm-1, the electrochemical window is 4.8V. The composite polymer electrolyte with a 1-dimensional nanofiller such as SiO2 nanowires provides a new way to polymer electrolytes with better electrochemical and mechanical performance for practical applications in lithium ion batteries.",

keywords = "Composite polymer electrolyte, Lithium ion batteries, Nanowires, SiO",

author = "P. Zhang and Yang, {L. C.} and Li, {L. L.} and Ding, {M. L.} and Wu, {Y. P.} and R. Holze",

year = "2011",

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AU - Zhang, P.

AU - Yang, L. C.

AU - Li, L. L.

AU - Ding, M. L.

AU - Wu, Y. P.

AU - Holze, R.

PY - 2011/9/1

Y1 - 2011/9/1

N2 - Composite polymer electrolytes prepared by adding SiO2 nanowires into P(VDF-HFP) are described. Their electrochemical and mechanical properties were improved by 3-dimensional network interaction between the nanowires and the polymer chains. The composite polymer membrane can tolerate a maximal stress of 27.8MPa. The ionic conductivity of the prepared gelled polymer electrolyte is up to 1.08×10-3Scm-1, the electrochemical window is 4.8V. The composite polymer electrolyte with a 1-dimensional nanofiller such as SiO2 nanowires provides a new way to polymer electrolytes with better electrochemical and mechanical performance for practical applications in lithium ion batteries.

AB - Composite polymer electrolytes prepared by adding SiO2 nanowires into P(VDF-HFP) are described. Their electrochemical and mechanical properties were improved by 3-dimensional network interaction between the nanowires and the polymer chains. The composite polymer membrane can tolerate a maximal stress of 27.8MPa. The ionic conductivity of the prepared gelled polymer electrolyte is up to 1.08×10-3Scm-1, the electrochemical window is 4.8V. The composite polymer electrolyte with a 1-dimensional nanofiller such as SiO2 nanowires provides a new way to polymer electrolytes with better electrochemical and mechanical performance for practical applications in lithium ion batteries.

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