Thermal shrinkage and microscopic shutdown mechanism of polypropylene separator for lithium-ion battery: In-situ ultra-small angle X-ray scattering study

Abstract

Structural variation and shutdown behavior of polypropylene separator for lithium-ion batteries upon heating have been investigated via in-situ ultra-small angle X-ray scattering (USAXS) tests. Structural parameters including porosity, specific interface and pore size have been successfully estimated by fitting the scattering intensity with craze model. The fitting results reveal that cylindrical pores are oriented in stretching direction with average length of 155nm and radius of 63nm. In-situ USAXS results show that the shutdown of the polypropylene separator initiated from the temperature of 152°C which is close to the onset of the melting temperature. The shutdown of the pores has been found to be originated from the melting of crystals which leads to the release of the internal shrink force. Two driving forces, i.e. shrinking force from oriented chains and surface tension of nanosized pores, have been revealed. It was demonstrated that the shrinking force is the major driving force at the initial stage and the surface tension controls the shutdown at the final stage.