Effect of varying the composition and nanostructure of organic carbonate-containing lyotropic liquid crystal polymer electrolytes on their ionic conductivity

Nanostructured composite electrolyte films consisting of a cross-linked lyotropic liquid crystal (LLC) monomer, an organic carbonate liquid electrolyte (propylene carbonate, dimethylcarbonate, diethylcarbonate) and a Li salt (LiClO 4 , LiBF 4 , LiPF 6 ) were systematically prepared and characterized at two electrolyte concentrations (0.245 and 1.0 m ) and four liquid loading levels (5, 15, 30, 50 wt %). The LLC morphology of the films was investigated using polarized light microscopy and powder X-ray diffraction; their ionic conductivity was investigated using AC impedance measurements. Higher liquid electrolyte loadings and Li salt concentrations generally increased ionic conductivity, regardless of the liquid electrolyte or salt used. Some mixed-phase LLC morphologies displayed good ionic conductivity; however, as initially prepared, these formulations were at the limit of liquid uptake. In contrast, composites with a type II bicontinuous cubic (Q II ) LLC phase containing ordered, three-dimensional interconnected nanopores exhibited good conductivity using much less liquid electrolyte and a lower Li salt concentration, indicating that this structure is more amenable to ion transport than less ordered/uniform morphologies. When wetted with electrolyte solution and integrated into Li/fluorinated carbon coin cells, the Q II films were sufficiently strong to act as an ion-conductive separator and displayed stable open-circuit potentials. Many of the mixed-phase films gave shorted cells. Nanostructured composite electrolyte films consisting of a cross-linked lyotropic liquid crystal monomer and varying amounts of an organic carbonate liquid electrolyte and a Li salt were systematically prepared and characterized for their ionic conductivity and ability to function as the separator membrane in a Li-metal/fluorinated carbon test cell. Films with a well-defined bicontinuous cubic phase were sufficiently strong to act as an ion-conductive separator and displayed stable open-circuit potentials, whereas the majority of the mixed-phase films gave shorted cells.