Chun-Jie Chang

In-situ template synthesis of a polymer/semiconductor nanohybrid using amphiphilic conducting block copolymers.

In this study, we synthesized organic/inorganic hybrid materials containing cadmium sulfide (CdS) nanoparticles using a novel amphiphilic conducting block copolymer as a synergistic structure-directing template and an efficient exciton quencher of the hybrid. The amphiphilic rod-coil block copolymer of polyphenylene-b-poly(2-vinyl pyridine) (PPH-PVP) was first prepared from its coil-coil precursor block copolymer of poly(1,3-cyclohexadiene)-b-poly(2-vinyl pyridine) (PCHD-PVP) by using sequential anionic polymerization followed by the aromatization reaction of converting the PCHD block to form conducting PPH. The synthesized PCHD-PVP block copolymers self-assembled into different bulk nanostructures of lamellae, cylinders, and spheres at a volume fraction similar to that of many coil-coil block copolymer systems. However, an enhanced chain-stiffness-induced morphological transformation was observed after the aromatization reaction. This is evidenced by the TEM observation in which both spherical and cylindrical structured PCHD-PVPs transform into lamellar structured PPH-PVPs after aromatization. In addition to the bulk-phase transformation, the rigid-rod characteristic of the conducting PPH block also affects the self-assembling property of the block copolymers in their solution state. CdS nanoparticles were synthesized in situ in a selective solvent of THF using PCHD-PVP and PPH-PVP micelles as nanoreactors. The PPH-PVP/Cd ion in THF exhibits a new ringlike structure of uniform size (approximately 50 nm) with PPH in the inner rim and complexed PVP/Cd ions in the outer rim as a result of the effects of strong intermolecular forces between PPH segments and the solvophobic interaction. CdS nanoclusters were subsequently synthesized in situ from the PPH-PVP/Cd(2+) ring structure, forming a nanohybrid with intimate contact between the PPH domain and CdS nanoparticles. In particular, we found that there is an efficient energy/electron transfer between the conducting PPH domain and CdS nanoparticles in the hybrid, resulting in an enhanced PL quenching effect. The novel nanohybrid shows the potential to be used for optoelectronic applications.

Effect of rod–rod interaction on self-assembly behavior of ABC π-conjugated rod–coil–coil triblock copolymers

A new class of ABC π-conjugated rod–coil–coil triblock copolymers of poly(diethylhexyloxy-p-phenylene vinylene)-b-poly (2-vinyl pyridine)-b-polystyrene (PPV-PVP-PS) was synthesized and its self-assembly behavior was explored. Three different triblock copolymers of PPV-PVP-PS1, PPV-PVP-PS2, and PPV-PVP-PS3, each with PPV, PS, and PVP, respectively, as the major species in the copolymers, were used to study the effects of copolymer composition and rod–rod interaction between PPV blocks on their morphology. Transmission electron microscopy (TEM), polarizing optical microscopy (POM), and simultaneously measured small-angle (SAXS) and wide-angle (WAXS) X-ray scattering experiments as a function of different annealing conditions revealed the details of the copolymer morphology, molecular packing, and their phase transitions. Despite their large differences in the rod volume fraction, fPPV, from 0.43 to 0.18, all three triblock copolymers adopted a self-assembled lamellar structure, in sharp constrast with the observation of many non-lamellar structures typically exhibited by ABC coil–coil–coil triblock copolymers with similar segregation strength. For PPV-PVP-PS1 with its major species PPV rod coupled with a single-phase symmetric PVP-PS diblock precursor, PPV-PVP-PS1 self-organized to form a triple-lamellar phase with each domain corresponding to the three respective blocks. Investigation of the molecular packing of PPV rods within their domain through the analysis of the 1D electron density profile suggests the PPV rods adopted a smectic C monolayer organization below its order–disorder transition temperature (TODT). For PPV-PVP-PS2 with its PS-rich asymmetric PVP-PS diblock precursor that displayed a disordered micelle structure, PPV-PVP-PS2 with fPPV of only 0.19 still exhibited a triple-lamellar phase with PPV forming a broken lamellar layer, thus preventing the excessive chain stretching of the coil blocks on the otherwise long-range ordered PPV lamellar phase. A similar broken triple-lamellar phase can also be observed for the PVP-rich PPV-PVP-PS3 with a low fPPV of only 0.18. Simultaneous SAXS and WAXS measurements show that all three triblock copolymers undergo the ordered lamella-to-disorder transition and the smectic/isotropic transition at the same temperature, indicating that the rod–rod interaction between PPV rods plays a critical role in forming and stabilizing these lamellar structures. The observation of the phase transformations is in good agreement with a recent mean-field prediction of a rod–coil–coil triblock copolymer system.