Thermally Resistant, Mechanically Robust, Enamel‐Inspired Hydroxyapatite/Polyethylene Nanocomposite Battery Separator

• Published in: Advanced functional materials Vol. 34; no. 7
• Main Authors: Yue, Honglei, Yao, Yifan, Li, Yanmei, Ding, Longjiang, Guo, Jianchao, Tang, Xuke, Li, Feng, Sun, Yunhou, Huang, Jinliang, Zhong, Haiqing, Yan, Qiang, Qi, Juanjuan, Zhang, Ao, Mei, Yong, Zhang, Yongbo, Wang, Hua, Chen, Ke
• Format: Journal Article
• Language: English
• Published: Hoboken Wiley Subscription Services, Inc 01.02.2024
• Subjects: Coefficient of friction; Elongation; Enamel; Energy dissipation; enhanced electrochemical properties; Finite element method; Heat treatment; Hydroxyapatite; Lithium-ion batteries; mammalian enamel inspired; Mechanical properties; nanocomposite polyethylene separators; Nanocomposites; Polyethylene; Polyethylenes; quasi‐continuous strategy; Robustness; Separators; Short circuits; Thermal resistance; Thermal runaway
• ISSN: 1616-301X; 1616-3028
• DOI: 10.1002/adfm.202308039

Microporous polyethylene (PE) membrane is a representative lithium‐ion battery (LIB) separators but regularly shrinks especially in high‐temperature conditions, and is facilely pierced while growing Li dendrites, leading to severe consequences such as short circuits, thermal runaway, and even explosion. Herein, this article reports a quasi‐continuous strategy that utilizes in situ enamel mineralization engineering followed by thermal treatment to easily develop a large‐area, 3D interlaced hydroxyapatite nanosheets array‐reinforced PE nanocomposite separator with robust mechanical properties and excellent resistance to thermal shrinkage. Specifically, the 120 °C‐heated nanocomposite possesses excellent breaking stress, an ultrahigh toughness of ≈434.4 MJ m−3, and an enhanced friction coefficient of ≈0.69, which are distinctly higher than those of commercial PE separators, respectively, and far exceeding those of reported ceramic modified‐PE separators. The elongation of the resultant nanocomposite can achieve an extraordinary ≈2456.4% without any fracture under a 180 °C‐heating temperature. In situ observation and finite element simulation indicate that the impressive mechanical and thermostable integration profits from the co‐effect of efficient energy dissipation at organic–inorganic interfaces and mechanically interlocked, mutually‐supported hybrid microstructure. The enamel‐inspired separator can be potentially applied in safer high‐temperature LIBs and this strategy provides a valuable guide to develop other high‐performance polymer‐based nanocomposites. A quasi‐continuous preparation strategy that utilizes in situ enamel mineralization engineering followed by thermal treatment is proposed to develop a large‐area, enamel‐3D interlaced hydroxyapatite nanosheets array‐reinforced polyethylene nanocomposite separator with robust mechanical properties and excellent resistance to thermal shrinkage. The nanocomposite separator can be potentially applied in safer high‐temperature Li‐ion batteries.