Influence of molecular weight on the phase behavior and structure formation of branched side-chain hairy-rod polyfluorene in bulk phase -: art. no. 041802

We report on an experimental study of the self-organization and phase behavior of hairy-rod pi-conjugated branched side-chain polyfluorene, poly[9,9-bis(2-ethylhexyl)-fluorene-2,7-diyl]-i.e., poly[2,7-(9,9-bis(2-ethylhexyl)fluorene] (PF2/6)-as a function of molecular weight (M-n). The results have been compared to those of phenomenological theory. Samples for which M-n=3-147 kg/mol were used. First, the stiffness of PF2/6, the assumption of the theory, has been probed by small-angle neutron scattering in solution. Thermogravimetry has been used to show that PF2/6 is thermally stable over the conditions studied. Second, the existence of nematic and hexagonal phases has been phenomenologically identified for lower and higher M-n (LMW, M-n < M-n(*) and HMW, M-n>M-n(*)) regimes, respectively, based on free-energy argument of nematic and hexagonal hairy rods and found to correspond to the experimental x-ray diffraction (XRD) results for PF2/6. By using the lattice parameters of PF2/6 as an experimental input, the nematic-hexagonal transition has been predicted in the vicinity of glassification temperature (T-g) of PF2/6. Then, by taking the orientation parts of the free energies into account the nematic-hexagonal transition has been calculated as a function of temperature and M-n and a phase diagram has been formed. Below T-g of 80 degrees C only (frozen) nematic phase is observed for M-n < M-n(*)=10(4) g/mol and crystalline hexagonal phase for M-n>M-n(*). The nematic-hexagonal transition upon heating is observed for the HMW regime depending weakly on M-n, being at 140-165 degrees C for M-n>M-n(*). Third, the phase behavior and structure formation as a function of M-n have been probed using powder and fiber XRD and differential scanning calorimetry and reasonable semiquantitative agreement with theory has been found for M-n >= 3 kg/mol. Fourth, structural characteristics are widely discussed. The nematic phase of LMW materials has been observed to be denser than high-temperature nematic phase of HMW compounds. The hexagonal phase has been found to be paracrystalline in the (ab0) plane but a genuine crystal meridionally. We also find that all these materials including the shortest 10-mer possess the formerly observed rigid five-helix hairy-rod molecular structure.