Construction of porous and hydrophilic polypropylene-based membrane with microphase separation in amorphous region.

Polypropylene (PP) membrane with low porosity and poor hydrophilicity limits the performance of lithium-ion batteries. In mechanism, the function of amorphous structure of precursor film on microporous structure of PP membrane is yet unknown. In this work, the porous and hydrophilic PP/reduced hydroxyl-modified polypropylene (PPrOH) membrane was fabricated by blending esterified-PPOH firstly and then hydrolyzing to introduce the hydrogen bond in amorphous region and avoid phase separation. The results showed that the hydrogen bond was successfully introduced into the amorphous region of PP/PPrOH film and led to an increase of physical crosslinking points. Therefore, a large region of microphase separation emerged in the PP/PPrOH membrane after cold stretching, which resulted in a 45.6 % increase of porosity at maximum compared to the PP membrane. Besides, the hydrophilicity of PP/PPrOH membrane was improved with the blend content exceeding 10 wt%. Eventually, the lithium-ion conductivity of PP/PPrOH-10 membrane enhanced by 37.5 % over the base PP membrane. This work provides a novel perspective for preparing hydrophilic PP membrane with high porosity. [Display omitted] • Introducing hydrogen bond in amorphous of PP film by melt blending with PPrOH. • Hydrogen crosslinking in amorphous results in more region of microphase separation at stretching. • Addition of PPrOH increases porosity by 45.6 % and enhances lithium-ion conductivity by 37.5 % compared to PP membrane. • Crosslinking density in amorphous is positively correlated with porosity of membrane. [ABSTRACT FROM AUTHOR]