What does this research mean for the field?

The in-situ nanoencapsulated silica/polyvinylidene fluoride (ISE-SiO2/PVDF) separator significantly enhances the safety and performance of lithium metal batteries by improving thermal stability, flame retardancy, and lithium ion transport. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to develop a safer lithium metal battery separator by using an in-situ nanoencapsulated composite material.

March 5, 2026Open Access

In-situ nanoencapsulated core-shell silica/polyvinylidene difluoride separators: Synergistically enhance the safety of lithium metal batteries

Key Points

This research aims to develop a safer lithium metal battery separator by using an in-situ nanoencapsulated composite material.
Developed a core-shell structured separator using electrospinning and low-temperature hydrolysis.
Coated polyvinylidene fluoride (PVDF) fibers with silica (SiO 2) to form a protective nanolayer.
Tested thermal stability, tensile strength, and cycling performance of the separator in battery applications.
Separator strength improved from 0.6 MPa to 2.2 MPa.
Shrinkage of the separator at 150 °C is approximately 0%, contrasting with 62% for traditional separators.
The separator supports over 250 stable charge-discharge cycles at a specific current density, with over 300 cycles for LiCoO 2 based batteries, maintaining a capacity retention of 58.79%.

Abstract

Regarding the safety risks caused by the high-temperature contraction and melting of traditional polyolefin separators in lithium metal batteries, an in-situ nanoencapsulated silica/polyvinylidene fluoride (ISE-SiO 2 /PVDF) composite separator with core-shell structure was prepared by electrospinning coupled low-temperature hydrolysis technology. The design uses PVDF fiber as the core, and the surface is uniformly coated with the thermally stable SiO 2 nanolayer in situ. The SiO 2 cladding synergistically strengthens the tensile strength of the separator (0.6 MPa → 2.2 MPa). At the same time, the excellent heat/oxygen barrier properties of SiO 2 are used to greatly enhance thermal stability (shrinkage rate at 150 °C, ISE-SiO 2 /PVDF: ∼0%, PE: ∼62%) and flame retardancy (touching the flame without burning), and build a thermal runaway barrier. More importantly, the inherent strong lithium ion affinity of SiO 2 not only induces the formation of low-energy barrier and highly ordered lithium ion transport channels (t Li+ = 0.45, σ = 1.04 mS cm −1 ), but also provides uniformly distributed lithium nucleation sites, which synergistically promotes the uniform deposition of lithium ions and may efficiently inhibits the uncontrollable growth of lithium dendrites. The Li||Li battery based on ISE-SiO 2 /PVDF separator can undergo stable cycling for more than 250 times under the conditions of 1 mA cm −2 /1 mAh cm −2 . The assembled LiCoO 2 (active material load: 10.9 mg)||Li battery can also be stably cycled more than 300 times, and still maintains a capacity retention rate of 58.79% (PE is 36.16%) at a high current density of 5C. This in-situ nanopackaging strategy cleverly combines organic flexibility and inorganic functionality, providing a new efficient way to develop high-safety and high-performance lithium metal battery separators. • The prepared ISE-SiO 2 /PVDF separator realizes the fine compounding of organic and inorganic phases at the nanoscale. • The SiO 2 layer improves flame retardancy and electrochemical properties, eliminating the defects of traditional separators. • The ISE-SiO 2 /PVDF separator offers a practical solution to the safety and longevity of lithium metal batteries.

In-situ nanoencapsulated core-shell silica/polyvinylidene difluoride separators: Synergistically enhance the safety of lithium metal batteries

Key Points

Abstract

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