Propagation Kinetics of the Radical Polymerization of Methylated Acrylamides in Aqueous Solution

Schrooten, Jens; Lacı́k, Igor; Stach, Marek; Hesse, Pascal; Buback, Michael

doi:10.1002/macp.201300357

Cited by 31 publications

(64 citation statements)

References 44 publications

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“…53,58 For methacrylamide, an increase in k p s by 32% has been observed in passing from 20 to 10 wt % monomer in aqueous solution. 62 Since SPR and MCR propagation are subject to the same effects of molecular environment, k p t may well reflect the same dependence on monomer concentration as does k Table 4 shows that k p t of AAm polymerization is much closer to the associated numbers for AA and BA than are the backbiting rate coefficients of these monomers (see Table 3). The k p t /k p s ratio for AAm, e.g., at 75°C is 0.35× 10 −3 , which is not too dissimilar from k p t /k p s = 1.0 × 10 −3 for AA (10 wt % in H 2 O) and k p t /k p s = 1.1 × 10 −3 for BA in 1.5 M in toluene.…”

Section: ■ Results and Discussionmentioning

confidence: 94%

Termination and Transfer Kinetics of Acrylamide Homopolymerization in Aqueous Solution

2015

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The single pulse−pulsed laser polymerization−electron paramagnetic resonance (SP−PLP−EPR) method affords the detailed kinetic analysis of acrylamide polymerization in aqueous solution. Highly time-resolved SP− PLP−EPR experiments for 10 and 20 wt % AAm were first carried out at −5°C, where only secondary propagating radicals (SPRs) occur. In a second step, the time evolution of midchain radicals (MCRs), produced from SPRs by backbiting, was measured at higher temperatures. The termination kinetics, including chainlength dependent termination of SPRs, the backbiting rate of SPRs, and the propagation rate of MCRs were determined. The rate coefficients from SP− PLP−EPR in conjunction with the known propagation rate coefficient of SPRs, enable the simulation of the kinetics and product properties of AAm radical polymerizations in aqueous solution.

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Section: ■ Results and Discussionmentioning

confidence: 94%

Termination and Transfer Kinetics of Acrylamide Homopolymerization in Aqueous Solution

2015

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“…On the other hand, the similarity between AAm and other acrylic monomers suggests that backbiting may occur, perhaps at higher temperatures than with acrylates and acrylic acid. This assumption is supported by the loss of overtone components in PLP–SEC experiments on DM‐AAm and AAm at higher temperatures . No similar loss is seen with acrylamides bearing an α ‐methyl group on the backbone .…”

Section: Introductionmentioning

confidence: 85%

“…Pulsed laser polymerization investigations accompanied by size‐exclusion‐chromatography (PLP–SEC) into AAm and N , N ‐dimethylacrylamide (DM‐AAm) polymerizations resulted in a pronounced laser‐pulse‐induced structure of the molar‐mass distribution even at low laser pulse repetition rates and temperatures up to 50 °C. This may be interpreted as an indication of backbiting either being absent or of only minor significance . On the other hand, the similarity between AAm and other acrylic monomers suggests that backbiting may occur, perhaps at higher temperatures than with acrylates and acrylic acid.…”

Section: Introductionmentioning

confidence: 96%

EPR Study of Backbiting in the Aqueous‐Solution Polymerization of Acrylamide

Kattner

Buback

2015

Macromol. Rapid Commun.

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Via electron paramagnetic resonance (EPR) spectroscopy, the type of radicals occurring during acrylamide (AAm) homopolymerization in aqueous solution is investigated between -5 and +100 °C. The radicals are produced photochemically under stationary conditions. Midchain AAm radicals (MCRs) are clearly identified by EPR which demonstrates that secondary propagating AAm radicals (SPRs) undergo backbiting reactions. Above 50 °C, the fraction of MCRs even exceeds the one of SPRs. The extent of backbiting is however well below the one in butyl acrylate polymerization at identical temperature.

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“…Most studies of polar monomer polymerization activity concerned acrylic acid, acrylamide, and their derivatives . The propagating chain growth and termination rate constants may be varied by changing the polymerization batch composition …”

Section: Introductionmentioning

confidence: 99%

Determination of Homopolymerization Kinetics of 10‐(N‐Methylacrylamido)‐decylphosphonic acid, Its Diethyl ester, and 10‐(Methacryloyloxy)‐decylphosphonic acid, and Their Copolymerization with Methyl methacrylate

Chmela

Pavlineč

Fiedlerová

et al. 2015

Macro Chemistry & Physics

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Two polymerizable phosphonic acids destined to be constituents of self-etch adhesives as well as a diethyl phosphonate bearing an N -methylacrylamide group are examined for their polymeriza tion and copolymerization activity in methanol between 45 and 65 °C. Polymerization proceeds readily through a thermal free radical initiator. The intensity exponents for the monomer and initiator are only slightly over 1 and ≈0.5, respectively, in accordance with the results typically observed for an ideal free radical polymerization with bimolecular termination. The specifi c feature of this process is the absence of auto-acceleration during the phosphonic acid monomer polymerization and polymer network formation in case of the phosphonate monomer. The kinetics of copolymerization with methyl methacrylate (MMA) are monitored by online 1 H NMR spectroscopy. Two copolymerization reactions for each pair of comonomers are suffi cient to evaluate the kinetic data using the Jaacks method, the Fineman-Ross method, and the nonlinear least squares method. All three methods give similar results for particular monomer/MMA couples.

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Propagation Kinetics of the Radical Polymerization of Methylated Acrylamides in Aqueous Solution

Cited by 31 publications

References 44 publications

Termination and Transfer Kinetics of Acrylamide Homopolymerization in Aqueous Solution

Termination and Transfer Kinetics of Acrylamide Homopolymerization in Aqueous Solution

EPR Study of Backbiting in the Aqueous‐Solution Polymerization of Acrylamide

Determination of Homopolymerization Kinetics of 10‐(N‐Methylacrylamido)‐decylphosphonic acid, Its Diethyl ester, and 10‐(Methacryloyloxy)‐decylphosphonic acid, and Their Copolymerization with Methyl methacrylate

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