Abstract:Fullerene derivatives in which an oligophenylenevinylene (OPV) group is attached to C 60 through a pyrrolidine ring have been prepared by 1,3-dipolar cycloaddition of the azomethine ylides generated in situ from the corresponding aldehydes and sarcosine. Electrochemical and photophysical studies have revealed that ground-state electronic interactions between the covalently bonded OPV moiety and the fullerene sphere are small. The photophysical investigations have also shown that both in dichloromethane and benzonitrile solution an efficient singlet-singlet OPV f C 60 photoinduced energy-transfer process takes place, and occurrence of electron transfer, if any, is by far negligible relative to energy transfer. The C 60 -OPV derivatives have been incorporated in photovoltaic devices, and a photocurrent could be observed showing that photoinduced electron transfer does take place under these conditions. However, the efficiency of the devices is limited by the fact that photoinduced electron transfer from the OPV moiety to the C 60 sphere must compete with an efficient energy transfer. The latter process, as studied in solution, leads to the population of the fullerene lowest singlet excited state, found to lie slightly lower in energy than the charge-separated state expected to yield electron/hole pairs. Thus, only a small part of the absorbed light is able to contribute effectively to the photocurrent.
A new class of water-soluble, amphiphilic star block copolymers with a large number of arms was
prepared by sequential atom transfer radical polymerization (ATRP) of n-butyl methacrylate (BMA) and poly(ethylene glycol) methyl ether methacrylate (PEGMA). As the macroinitiator for the ATRP, a 2-bromoisobutyric
acid functionalized fourth-generation hyperbranched polyester (Boltorn H40) was used, which allowed the
preparation of star polymers that contained on average 20 diblock copolymer arms. The synthetic concept was
validated by AFM experiments, which allowed direct visualization of single molecules of the multiarm star block
copolymers. DSC and SAXS experiments on bulk samples suggested a microphase-separated structure, in agreement
with the core−shell architecture of the polymers. SAXS experiments on aqueous solutions indicated that the star
block copolymers can be regarded as unimolecular micelles composed of a PBMA core and a diffuse PPEGMA
corona. The ability of the polymers to encapsulate and release hydrophobic guests was evaluated using 1H NMR
spectroscopy. In dilute aqueous solution, these polymers act as unimolecular containers that can be loaded with
up to 27 wt % hydrophobic guest molecules.
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This work aims at establishing a link between process conditions and resulting micromechanical properties for aminoplast core/shell microcapsules. The investigated capsules were produced by the in situ polymerization of melamine formaldehyde resins, which represents a widely used and industrially relevant approach in the field of microencapsulation. Within our study, we present a quantitative morphological analysis of the capsules' size and shell thickness. The diameter of the investigated capsules ranged from 10 to 50 μm and the shell thickness was found in a range between 50 and 200 nm. As key parameter for the control of the shell thickness, we identified the amount of amino resin per total surface area of the dispersed phase. Mechanical properties were investigated using small deformations on the order of the shell thickness by atomic force microscopy with a colloidal probe setup. The obtained capsule stiffness increased with an increasing shell thickness from 2 to 30 N/m and thus showed the same trend on the process parameters as the shell thickness. A simple analytical model was adopted to explain the relation between capsules' geometry and mechanics and to estimate the elastic modulus of the shell about 1.7 GPa. Thus, this work provides strategies for a rational design of microcapsule mechanics.
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