Evaluation of asymmetric poly(vinylidene fluoride)-coated polyimide separator with three-dimensionally homogeneous microporous structure for high-safety lithium-ion battery

Hui Chang; Guohong Kang; Zengqi Zhang; Wei Liu; Yongcheng Jin

doi:10.20517/energymater.2023.143

Energy Materials ›› 2024, Vol. 4 ›› Issue (5) :400052 DOI: 10.20517/energymater.2023.143

Article

Evaluation of asymmetric poly(vinylidene fluoride)-coated polyimide separator with three-dimensionally homogeneous microporous structure for high-safety lithium-ion battery

Hui Chang ¹^,^#
, Guohong Kang ¹^,^#
, Zengqi Zhang ²^,^*
, Wei Liu ¹^,^*
, Yongcheng Jin ¹^,^*

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Abstract

Safety hazards associated with separators in lithium-ion batteries are more pronounced in light of the significant improvement of energy density of batteries, hindering their wide application. In this research, asymmetric poly (vinylidene fluoride) (PVDF)-coated polyimide separators with three-dimensionally homogeneous microporous (3DHM API/PVDF) structure are prepared, in which a PVDF layer with a thickness of 6 μm on one side of polyimide. Polyimide, as the base film, has a high heat-resistant temperature which ensures that as-prepared separators will not be shrunk and burned. The coated PVDF layer imparts 3DHM API/PVDF with thermal shutdown function at 175 °C due to the melting of PVDF. The temperature difference between the shutdown and meltdown temperature is over 100 °C, ensuring that the LIB assembled with 3DHM API/PVDF is safe for use. Moreover, the interconnected microporous structure of the separator facilitates the formation of 3D Li⁺ transport pathways and uniformity of lithium deposition, suppressing lithium dendrite growth. The coin cells assembled by 3DHM API/PVDF exhibit similar electrochemical performance to that of a commercial polypropylene separator at room temperature. Therefore, the novel 3DHM API/PVDF separator may be a promising candidate for a significantly safer LIB.

Keywords

Composite separator / flame resistance / shutdown function / functional polymeric coating / three-dimensionally homogeneous microporous structure / lithium-ion battery

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Hui Chang, Guohong Kang, Zengqi Zhang, Wei Liu, Yongcheng Jin. Evaluation of asymmetric poly(vinylidene fluoride)-coated polyimide separator with three-dimensionally homogeneous microporous structure for high-safety lithium-ion battery. Energy Materials, 2024, 4(5): 400052 DOI:10.20517/energymater.2023.143

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