A non‐Newtonian fluidic cellulose‐modified glass microfiber separator for flexible lithium‐ion batteries

Ying Zhu; Kaiyue Cao; Wanke Cheng; Suqing Zeng; Shuo Dou; Wenshuai Chen; Dawei Zhao; Haipeng Yu

doi:10.1002/eom2.12126

EcoMat (Aug 2021)

A non‐Newtonian fluidic cellulose‐modified glass microfiber separator for flexible lithium‐ion batteries

Ying Zhu,
Kaiyue Cao,
Wanke Cheng,
Suqing Zeng,
Shuo Dou,
Wenshuai Chen,
Dawei Zhao,
Haipeng Yu

Affiliations

Ying Zhu: Key Laboratory of Bio‐based Material Science and Technology of Ministry of Education Northeast Forestry University Harbin China
Kaiyue Cao: Key Laboratory of Bio‐based Material Science and Technology of Ministry of Education Northeast Forestry University Harbin China
Wanke Cheng: Key Laboratory of Bio‐based Material Science and Technology of Ministry of Education Northeast Forestry University Harbin China
Suqing Zeng: Key Laboratory of Bio‐based Material Science and Technology of Ministry of Education Northeast Forestry University Harbin China
Shuo Dou: Key Laboratory of Bio‐based Material Science and Technology of Ministry of Education Northeast Forestry University Harbin China
Wenshuai Chen: Key Laboratory of Bio‐based Material Science and Technology of Ministry of Education Northeast Forestry University Harbin China
Dawei Zhao: Key Laboratory on Resources Chemicals and Materials of Ministry of Education Shenyang University of Chemical Technology Shenyang China
Haipeng Yu: Key Laboratory of Bio‐based Material Science and Technology of Ministry of Education Northeast Forestry University Harbin China

DOI: https://doi.org/10.1002/eom2.12126
Journal volume & issue: Vol. 3, no. 4
pp. n/a – n/a

Abstract

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Abstract The separator is of great importance for regulating ion transmission, maintaining electrode stability, and device safety in lithium‐ion batteries. Despite their many advantages, glass microfiber separators have shortcomings that often give rise to poor cycle performance and fatal short‐circuit risk when used in flexible batteries. Here, we propose the use of a scalable non‐Newtonian fluidic cellulose permeation‐diffusion strategy to develop a cellulose/glass microfiber composite film with an hourglass‐gradient structure. Due to the unique gradient morphology resulting from the presence of cellulose macromolecules, the as‐prepared composite film showed an improved surface mass density, adjustable pore structure, controllable ion transport, ideal mechanical flexibility, and robustness. When used as the separator in an assembled lithium‐ion battery, the composite film exhibited rapid ion diffusion and Li dendrite inhibition, which endowed the battery with excellent cycle stability (specific capacity of 108.5 mAh g−1 after 1000 cycles) and good rate performance. This composite film shows great potential application in flexible lithium‐ion batteries including but not limited to pouch cells.

Published in EcoMat

ISSN: 2567-3173 (Online)
Publisher: Wiley
Country of publisher: Australia
LCC subjects: Technology: Mechanical engineering and machinery: Renewable energy sources; Geography. Anthropology. Recreation: Environmental sciences
Website: https://onlinelibrary.wiley.com/journal/25673173

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