Revealing an Interconnected Interfacial Layer in Solid-State Polymer Sodium Batteries

Journal article (2019)

Authors

C. Zhao Chinese Academy of Sciences

Lilu Liu Chinese Academy of Sciences, University of Chinese Academy of Sciences

Yaxiang Lu University of Chinese Academy of Sciences, Chinese Academy of Sciences

M. Wagemaker RST/Storage of Electrochemical Energy -

Liquan Chen Chinese Academy of Sciences

Yong Sheng Hu Yangtze River Delta Physics Research Center, Liyang, University of Chinese Academy of Sciences, Chinese Academy of Sciences

Research Group

RST/Storage of Electrochemical Energy () (TU Delft)

DOI: https://doi.org/10.1002/anie.201909877

Composite metal anodes Interfacial layers Sodium batteries Solid polymer electrolytes Stable cycling

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Published Date

2019

Language

English

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Faculty

Applied Sciences

Department

RST/Radiation, Science and Technology

Research Group

RST/Storage of Electrochemical Energy

Abstract

Replacing the commonly used nonaqueous liquid electrolytes in rechargeable sodium batteries with polymer solid electrolytes is expected to provide new opportunities to develop safer batteries with higher energy densities. However, this poses challenges related to the interface between the Na-metal anode and polymer electrolytes. Driven by systematically investigating the interface properties, an improved interface is established between a composite Na/C metal anode and electrolyte. The observed chemical bonding between carbon matrix of anode with solid polymer electrolyte, prevents delamination, and leads to more homogeneous plating and stripping, which reduces/suppresses dendrite formation. Full solid-state polymer Na-metal batteries, using a high mass loaded Na₃V₂(PO₄)₃ cathode, exhibit ultrahigh capacity retention of more than 92 % after 2 000 cycles and over 80 % after 5 000 cycles, as well as the outstanding rate capability.

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