As
an important component, the properties of separators directly
affect the capacity, life, and safety performance of lithium-ion batteries
(LIBs). The high thermal stability and safety application value of
the thermoplastic elastomer poly(styrene-b-isoprene-b-styrene) block copolymer (SIS) with different block ratios
were explored to enhance the thermal stability and mechanical strength
of the cross-linked polyacrylonitrile (PAN) membranes by vulcanization
cross-linking and heat treatment. Among these membranes, the sample
named the S/PAN/SIS-4019 separator was confirmed to be a self-closing
separator that can cope with the thermal runaway, attributing to the
continued fusion of the SIS soft and hard segments in the cross-linked
structure under high-temperature heat treatment. Moreover, the tensile
strength of S/PAN/SIS-4019 separator increased to 17.49 MPa, which
was better than that of Celgard 2400, PAN, and other inlay separators.
Using S/PAN/SIS-4019 as a battery separator, lithium-ion batteries
showed a superior electrochemical performance compared to the usage
of Celgard 2400. Owing to the stable pore structure and thermally
protected self-shutdown mechanism, the overall properties of the obtained
cross-linked separator were improved in terms of higher thermal stability,
high ionic conductivity, and electrochemical properties.