Abstract
RAFT dispersion polymerization of 2,2,2-trifluoroethyl methacrylate (TFEMA) is performed in n-dodecane at 90 °C using a relatively short poly(stearyl methacrylate) (PSMA) precursor and 2-cyano-2-propyl dithiobenzoate (CPDB). The growing insoluble poly(2,2,2-trifluoroethyl methacrylate) (PTFEMA) block results in the formation of PSMA–PTFEMA diblock copolymer nano-objects via polymerization-induced self-assembly (PISA). GPC analysis indicated narrow molecular weight distributions (Mw/Mn ≤ 1.34) for all copolymers, with 19F NMR studies indicating high TFEMA conversions (≥95%) for all syntheses. A pseudo-phase diagram was constructed to enable reproducible targeting of pure spheres, worms, or vesicles by varying the target degree of polymerization of the PTFEMA block at 15–25% w/w solids. Nano-objects were characterized using dynamic light scattering, transmission electron microscopy, and small-angle X-ray scattering. Importantly, the near-identical refractive indices for PTFEMA (1.418) and n-dodecane (1.421) enable the first example of highly transparent vesicles to be prepared. The turbidity of such dispersions was examined between 20 and 90 °C. The highest transmittance (97% at 600 nm) was observed for PSMA9–PTFEMA294 vesicles (237 ± 24 nm diameter; prepared at 25% w/w solids) in n-dodecane at 20 °C. Interestingly, targeting the same diblock composition in n-hexadecane produced a vesicle dispersion with minimal turbidity at a synthesis temperature of 90 °C. This solvent enabled in situ visible absorption spectra to be recorded during the synthesis of PSMA16–PTFEMA86 spheres at 15% w/w solids, which allowed the relatively weak n→π* band at 515 nm assigned to the dithiobenzoate chain-ends to be monitored. Unfortunately, the premature loss of this RAFT chain-end occurred during the RAFT dispersion polymerization of TFEMA at 90 °C, so meaningful kinetic data could not be obtained. Furthermore, the dithiobenzoate chain-ends exhibited a λmax shift of 8 nm relative to that of the dithiobenzoate-capped PSMA9 precursor. This solvatochromatic effect suggests that the problem of thermally labile dithiobenzoate chain-ends cannot be addressed by performing the TFEMA polymerization at lower temperatures.
Highlights
Block copolymer self-assembly in solution has been studied for almost six decades.[1−3] Traditionally, this has been achieved via post-polymerization processing techniques such as a solvent switch[4] or thin film rehydration.[5]
Kinetic data was obtained for the RAFT dispersion polymerization of trifluoroethyl methacrylate (TFEMA) at 90 °C when targeting PSMA9−PTFEMA200 vesicles at 20% w/w solids in n-dodecane
When targeting PSMA9−PTFEMA200 vesicles, 19F NMR spectroscopy studies indicated that more than 95% TFEMA conversion can be achieved within 5 h
Summary
Block copolymer self-assembly in solution has been studied for almost six decades.[1−3] Traditionally, this has been achieved via post-polymerization processing techniques such as a solvent switch[4] or thin film rehydration.[5]. To record high-quality visible absorption spectra during the RAFT dispersion polymerization of TFEMA, three criteria must be fulfilled.[23] First, nanoparticle scattering must be minimized (preferably eliminated) by obtaining an isorefractive dispersion at the reaction temperature.[23] For the current PISA formulation, this can be achieved by employing n-hexadecane as a solvent at 90 °C (see Figure 6) while targeting relatively small PSMA16−PTFEMA86 spherical nanoparticles (in this case, DLS studies indicate a z-average diameter of 26 nm and a PDI of 0.05). Our observations suggest that such in situ visible absorption spectroscopy experiments are best undertaken when using trithiocarbonate RAFT agents because the corresponding endgroups exhibit much better thermal stability and do not suffer from any discernible blue shift in the λmax for their relatively weak visible absorption band
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