Group Transfer Polymerization

Rikkou-Kalourkoti, Maria; Webster, Owen W.; Patrickios, Costas S.

doi:10.1002/0471440264.pst603

Cited by 7 publications

(11 citation statements)

References 61 publications

(41 reference statements)

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“…[3] The scope of accessible monomers for zirconocene-mediated GTP was broadened in 2004 by Mariott and Chen. They introduced highly active chiral ansa-metallocenium enolatec ations (rac-(C 2 H 4 (Ind) 2 3 ] À )f or the isoselective polymerization of methyacrylates (e.g.,m ethyland n-butylmethacrylate) and various acrylamides.T he polymerization proceeded in al iving, monometallic and intramolecular coordinative-conjugate-addition mechanism via ac yclic ester enolate intermediate (Scheme 2, right). [11d, e, 20] As sustainability is an emergingt opic in the field of macromolecular chemistry,C hen et al investigatedt he polymerization catalysis of renewable methylene butyrolactones by GTP ( Figure 1).…”

Section: Catalysts In Group-transfer Polymerizationmentioning

confidence: 99%

“…Therefore, this polymerization type is predestinated for the synthesis of functional polymers including block, star-and graft-copolymers ( Figure 1). [2] In this concept article, we include the term "tacticity" as ac haracteristico ff unctional polymers, since the accurate control of stereoregularity enables the design of (co)polymers with tunable glass-transition/melting temperatures associated with designed stress-strain-properties. Stereo-regular polymers often exhibit physicala nd mechanical properties superior to their stereo-random analogues.…”

Section: Introductionmentioning

confidence: 99%

“…[9 10] In GTP,t his major drawback is eliminated by the stabilizationo ft he growing chain end. [2] Therefore, GTP isl ess sensitive to temperature, allowingt op erform polymerizations at up to 100 8C. This is advantageousf rom ap ractical as well as an economicp erspective.…”

Section: Introductionmentioning

confidence: 99%

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Metal‐Catalyzed Group‐Transfer Polymerization: A Versatile Tool for Tailor‐Made Functional (Co)Polymers

Adams

Pahl

Rieger

2017

Chemistry A European J

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Accommodating the increasing demand for tailor-made polymers is a major goal in polymer chemistry. Therefore, the investigation of polymerization techniques, which allow the precise synthesis of macromolecules is of exceptional interest. Ionic or controlled radical polymerization are capable living-type methods for the generation of uniform polymers. However, even these approaches reach their limits in certain issues. In the last decades, group-transfer polymerization (GTP) and especially metal-catalyzed GTP have proven to give access to a plethora of tailor-made homo- and copolymers based on α,β-unsaturated monomers. Thereby, GTP has established its potential in the development of functional and smart polymers. This concept article highlights the most significant progress in metal-catalyzed GTP with a focus on functional (co)polymers including different polymeric architectures and microstructures.

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Section: Catalysts In Group-transfer Polymerizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Metal‐Catalyzed Group‐Transfer Polymerization: A Versatile Tool for Tailor‐Made Functional (Co)Polymers

Adams

Pahl

Rieger

2017

Chemistry A European J

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“…The presence of hydrophobic segments has several important implications, namely capability of swelling in organic solvents (in addition to water), lower swelling in water compared to the fully hydrophilic polymer network counterparts, and self-organization in water with the formation of hydrophobic, micelle-like, water-free domains . This self-organization may further enhance the mechanical properties of the targeted DNs. − This enhancement would be in addition to that imparted through the homogeneity of these materials which are prepared via quasi-living/controlled polymerization chemistries, including group transfer polymerization (GTP), atom transfer radical polymerization (ATRP), and reversible addition–fragmentation chain transfer (RAFT) polymerization.…”

Section: Introductionmentioning

confidence: 99%

Double Networks Based on Amphiphilic Cross-Linked Star Block Copolymer First Conetworks and Randomly Cross-Linked Hydrophilic Second Networks

et al. 2016

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This study presents the preparation and characterization of double networks (DN) based on a first amphiphilic polymethacrylate conetwork (APCN) and a second polyacrylamide network. The APCN first network comprised interconnected “in–out” star copolymers of 2-(dimethylamino)ethyl methacrylate (DMAEMA, hydrophilic ionizable monomer) and 2-ethylhexyl methacrylate (EHMA, hydrophobic comonomer) or lauryl methacrylate (LauMA, second hydrophobic comonomer), synthesized using group transfer polymerization, following one-pot, sequential, monomer, and hydrophobic cross-linker (ethylene glycol dimethacrylate, EGDMA) additions. The second network was prepared by the aqueous photopolymerization of acrylamide (AAm) at two different concentrations, 2 and 5 M, and N,N′-methylenebis(acrylamide) cross-linker in the presence of the fully ionized (via HCl addition) APCN. After synthesis, all DNs and single (first and second) (co)networks, equilibrium-swollen in water, were characterized in terms of their mechanical properties in compression. The DNs exhibited improved mechanical properties (stress and strain at break, and elastic modulus) compared to the corresponding single networks. Better reinforcement was achieved in the DNs whose APCN first networks bore a lower hydrophobic content and whose hydrophobic monomer was EHMA rather than LauMA. The best DN exhibited stress at break above 8 MPa and strain at break nearly 80%, close to the values of the best DNs in the literature. Nanoindentation studies were also performed on selected DNs which proved again the enhanced mechanical properties of the present DNs, manifested as high resistance to penetration and low creep displacement. Small-angle X-ray scattering (SAXS) indicated a broad correlation peak for all APCN first networks, suggestive of microphase separation with short-range order, arising from the presence of the hydrophobic segments. The single correlation peak was preserved in the SAXS profiles of the DNs, which was, however, shifted to lower q-values, consistent with further network swelling. Despite the SAXS evidence for only weak phase separation on the nanoscale in the DNs, half of the water-swollen DNs (the ones with a 5 M AAm concentration in the second network) exhibited strong birefringence which probably arose from the stretching of the charged DMAEMA segments rather than the presence of anisotropic nanophases.

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“…de ketal-containing, [21][22][23][24][25][26][27][28] dimethacrylate cross-linker to accomplish the star interconnection and/or the formation of the star core. Although the polymerizations could have been performed using a controlled radical polymerization method, [29] such as atom transfer radical polymerization or reversible addition-fragmentation radical polymerization, a type of living oxyanionic polymerization, group transfer polymerization (GTP) [30][31][32][33][34][35] was used instead. GTP is suited for the polymerization of methacrylates up to medium molecular weights, with the important advantages of operability at room temperature and very fast kinetics, requiring only 5-10 min per polymerization step.…”

Section: Introductionmentioning

confidence: 99%

Networks Based on “Core‐First” Star Polymers End‐Linked Using a Degradable Ketal Cross‐Linker: Synthesis, Characterization, and Cleavage

Kepola

Patrickios

2017

Macro Chemistry & Physics

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out of every cross-linking core (crosslinking node functionality) is characterized by a rather broad distribution. We also developed a variation of this method, requiring only a monofunctional initiator, in which star polymers are first prepared using either the "arm-first" or the "corefirst" strategy, followed again by the addition of cross-linker to interconnect the stars to a quasimodel network. [4] Thus, our above-described methods represent a compromise between ease of synthesis and structural control, employing a onepot sequential procedure to yield polymer networks with a good control in the elastic chain length but less control in the core functionality.In the past 20 years, we developed many quasimodel polymer network families, based on end-linked linear chains or star copolymers. In addition to purely hydrophobic and hydrophilic homopolymer systems, more complex ones were also developed, most notable of which were the amphiphilic systems, combining both hydrophobic and hydrophilic segments. [5][6][7] Amphiphilic polymer conetworks (APCNs) self-assemble in water, phase separating at the nanoscale, and yielding hydrophilic and hydrophobic domains of nanoscopic dimensions, as well as a huge interfacial area between the nano phases. These attributes endow APCNs with a great utility in a variety of applications, including uses as the material for soft contact lenses, [8] matrices for drug delivery [9] and tissue engineering, [10] and porous scaffolds for phase transfer (bio)catalysis. [11] Other complex quasimodel polymer network systems we developed include polyampholytic ones, [12,13] comprising positively and negatively ionizable polymer segments, [14,15] and double-hydrophilic ones, comprising both hydrophilic polymer segments, of which one was ionizable and the other nonionic. [16,17] Another important development within quasimodel polymer networks was the introduction of degradability, either through a degradable cross-linker [18] or through a degradable bifunctional initiator, [19] with the latter being more demanding than the former, arising from the difficulties associated with the synthesis, purification, and the stability of degradable bifunctional initiators.In the present manuscript, we report the preparation, characterization, and cleavage of degradable quasimodel poly mer networks based on interconnected "core-first" star [20] poly(methyl methacrylate)s (polyMMAs), using a degradable, Group Transfer PolymerizationSequential group transfer polymerization of cross-linker, monomer (methyl methacrylate), and cross-linker again is used to prepare cleavable polymer networks based on interconnected "core-first" star polymers. By employing a degradable and a nondegradable cross-linker, four networks are prepared. While cleavage of the degradable cross-linker residues leads to complete polymer network dissolution, the degradation products do not always display the expected molecular weight features. These products are the expected in the case of the network prepared using only the degradable cross-li...

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Group Transfer Polymerization

Cited by 7 publications

References 61 publications

Metal‐Catalyzed Group‐Transfer Polymerization: A Versatile Tool for Tailor‐Made Functional (Co)Polymers

Metal‐Catalyzed Group‐Transfer Polymerization: A Versatile Tool for Tailor‐Made Functional (Co)Polymers

Double Networks Based on Amphiphilic Cross-Linked Star Block Copolymer First Conetworks and Randomly Cross-Linked Hydrophilic Second Networks

Networks Based on “Core‐First” Star Polymers End‐Linked Using a Degradable Ketal Cross‐Linker: Synthesis, Characterization, and Cleavage

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