The mechanism of reversible-deactivation radical polymerization (RDRP) mediated by chloro-substituted amine−bis(phenolate)iron complexes was studied via a combination of Mossbauer, EPR, NMR, and online Vis/NIR spectroscopy. It was found that styrene polymerization operates via an atom-transfer radical polymerization (ATRP) mechanism when alkyl halide is present, whereas an interplay between ATRP and organometallic-mediated radical polymerization (OMRP) equilibria occurs during MMA polymerization. The preparation of the amine−bis-(phenolate)iron(II) complex, [O 2 NN′]Fe II , allowed polymerizations to be performed under an OMRP-only regime free of alkyl halide that yields dispersities as low as 1.29 for MMA polymerization.
■ INTRODUCTIONReversible-deactivation radical polymerization (RDRP) enables the synthesis of polymeric materials with precisely tailored topologies, architectures, chain lengths, functionalities, and narrow molar-mass distributions. 1−3 Fe-based systems are particularly attractive for use in RDRP due to the low toxicity and broad availability of Fe. 4,5 Fe catalysts operate in two RDRP techniques, i.e., atom-transfer radical polymerization (ATRP) and organometallic-mediated radical polymerization (OMRP). 6−11 Both methods are based on a metal-mediated activation−deactivation equilibrium of propagating radicals involving the Fe catalyst in different oxidation states.Fe-mediated ATRP has been reported using iron(II) and iron(III) halides with amines, imines, and phosphines as ligands for in situ catalyst formation. 6,11,12 ATRP mediated by iron halides has also been performed without the addition of external ligands but by using coordinating solvents or by adding ammonium salts for the purpose of charge separation. 13−18 Femediated OMRP has been studied far less frequently, with acetylacetonate-, porphyrin-, and Schiff base-ligated Fe complexes offering reasonable levels of control. 19,20 Even in apparently well-defined Fe-mediated RDRP systems, interesting mechanistic features have been observed under closer experimental and computational scrutiny. For instance, an interplay between ATRP and catalytic chain transfer (CCT) was reported for a series of α-diimine iron complexes, R1,R2 [NN]FeCl 2 . 21−27 In this case, the nature of the ligand was found to determine the dominant polymerization mechanism, with electron-donating groups favoring ATRP and yielding halogen-terminated polymers with well-controlled molar masses. Conversely, ligands with electron-withdrawing groups were found to favor CCT, with the instability of the organometallic species resulting in β-hydrogen elimination to yield low molar mass, olefin-terminated polymers.Amine−bis(phenolate)iron complexes, [O 2 NN′]FeCl, facilitate efficient RDRP of substituted styrenes and methyl methacrylate (MMA) with dispersities as low as 1.07. 28,29 The kinetic insight obtained from these reactions suggests a dual-mechanistic control, involving both ATRP and OMRP, which is in agreement with computational studies. 30 However, the expected Fe species...
