RAFT solution polymerization of N-(2-(methacryoyloxy)ethyl)pyrrolidone (NMEP) in ethanol at 70 degrees C was conducted to produce a series of PNMEP homopolymers with mean degrees of polymerization (DP) varying from 31 to 467. Turbidimetry was used to assess their inverse temperature solubility behavior in dilute aqueous solution, with an LCST of approximately 55 degrees C being observed in the high molecular weight limit. Then a poly(glycerol monomethacylate) (PGMA) macro-CTA with a mean DP of 63 was chain-extended with NMEP using a RAFT aqueous dispersion polymerization formulation at 70 degrees C. The target PNMEP DP was systematically varied from 100 up to 6000 to generate a series of PGMA(63)-PNMEPx diblock copolymers. High conversions (>= 92%) could be achieved when targeting up to x = 5000. GPC analysis confirmed high blocking efficiencies and a linear evolution in Mn with increasing PNMEP DP. A gradual increase in M-w/M-n was also observed when targeting higher DPs. However, this problem could be minimized (M-w/M-n < 1.50) by utilizing a higher purity grade of NMEP (98% vs 96%). This suggests that the broader molecular weight distributions observed at higher DPs are simply the result of a dimethacrylate impurity causing light branching, rather than an intrinsic side reaction such as chain transfer to polymer. Kinetic studies confirmed that the RAFT aqueous dispersion polymerization of NMEP was approximately four times faster than the RAFT solution polymerization of NMEP in ethanol when targeting the same DP in each case. This is perhaps surprising because both H-1 NMR and SAXS studies indicate that the core-forming PNMEP chains remain relatively solvated at 70 degrees C in the latter formulation. Moreover, dissolution of the initial PGMA(63)-PNMEPx particles occurs on cooling from 70 to 20 degrees C as the PNMEP block passes through its LCST. Hence this RAFT aqueous dispersion polymerization formulation offers an efficient route to a high molecular weight water-soluble polymer in a rather convenient low-viscosity form. Finally, the relatively expensive PGMA macro-CTA was replaced with a poly(methacrylic acid) (PMAA) macro-CTA. High conversions were also achieved for PMAA(85)-PNMEPx diblock copolymers prepared via RAFT aqueous dispersion polymerization for x <= 4000. Again, better control was achieved when using the 98% purity NMEP monomer in such syntheses.

• 出版日期2016-6-28