| This thesis discusses three topics in the general area of hydrogen bonded polymer blends. The first pertains to the blending of flame retardant polyphosphazenes. Poly[bis(n-alkyoxy)phosphazenes] blends with poly(butyl methacrylate- co-4-vinyl phenol) (BMAVPh) were initially studied. These results were compared to BMAVPh blends of analogous poly (vinyl n-alkyl ethers) and the phase behavior was similar. Next, poly[bis(carboxylatophenoxy)phosphazene] blends with a structural polyurethane foam were prepared via reactive mixing. The combustion behavior of these foams was analyzed qualitatively, by a horizontal flame test, and quantitatively, by oxygen index (OI) measurements. Both of these tests indicated a modest increase in flame resistance at loadings of 20 wt% and above. In the second topic, equilibrium constants determined from low molecular weight mixtures were used to successfully predict the phase behavior of analogous polymer blends. Due consideration was given to intramolecular screening and functional group accessibility, factors that are a direct consequence of chain connectivity. In the third topic, polymer blends involving an alternating 1:1 copolymer of tetrafluoroethylene (TFE) and a hexafluoroisopropanol modified vinyl ether (HFIPVE) were studied. This copolymer is interesting for both experimental and theoretical studies of the phase behavior of polymer blends because (1) it is amorphous and has a relatively low glass transition temperature (12°C); (2) it has a relatively low solubility parameter (≈7 (cal.cm−3)−0.5); (3) it is soluble in moderately polar solvents, and (4) it contains the hexafluoroisopropanol group that is a strong hydrogen bond donor. Experimental infrared and thermal analysis studies of polymer blends with (co)polymers containing acetoxy, methacrylate and aliphatic ether groups were studied and compared to theoretical predictions of miscibility maps. |
