Effects of Functionality and Charge in the Design of Acrylic Polymers
MetadataShow full item record
Hydroxy-functional random and block copolymers of n-butyl acrylate (nBA) and 2-hydroxyethyl acrylate were synthesized using nitroxide mediated polymerization. Controlled polymerization was demonstrated, resulting in narrow polydispersities and linear molecular weight vs. conversion plots. In situ FTIR spectroscopy monitored the polymerizations and revealed pseudo first order rate kinetics for random copolymerizations. Protection of the hydroxyl using trimethylsilyl chloride alleviated isolation issues of amphiphilic polymer products. For the first time zwitterion-containing copolymers were electrospun to form nanoscale fibers with diameters as low as 100 nm. Free radical copolymerization of nBA and sulfobetaine methacrylamide produced zwitterionic copolymers with 6-13 mol % betaine. Dynamic mechanical analysis revealed a rubbery plateau and biphasic morphology similar to ionomers. Electrospinning from chloroform/ethanol solutions (80/20 v/v) at 2-7 wt % afforded polymeric fibers at viscosities below 0.02 Paâ ¢s, which is the lowest viscosity observed for fiber formation in our laboratories. We hypothesized that intermolecular interactions rather than chain entanglements dominated the electrospinning process.
Solution rheology of zwitterionic copolymers containing 6 and 9 mol % sulfobetaine methacrylate functionality revealed two concentration regimes with a boundary at ~1.5 â 2.0 wt %, regardless of molecular weight. This transition occurred at an order of magnitude lower specific viscosity than the entanglement concentration (Ce) for poly(nBA), and correlated to the onset of fiber formation in electrospinning. Comparison to existing models for polymer solution dynamics showed closest agreement to Rubinsteinâ s theory for associating polymers, in support of our hypothesis that zwitterionic interactions dominate solution dynamics.
The effect of ionic liquid (IL) uptake on mechanical properties and morphology of zwitterionic copolymers was explored using 1-ethyl-3-methylimidazolium ethylsulfate (EMIm ES). Dynamic mechanical analysis and impedance spectroscopy revealed a significant change in properties above a critical uptake of ~10 wt % IL. X-ray scattering revealed a significant swelling of the ionic domains at 15 wt % IL, with a 0.3 nm-1 shift in the ionomer peak to lower scattering vector. Results indicated the water-miscible IL preferentially swelled ionic domains of zwitterionic copolymers.
- Doctoral Dissertations