Synthesis, characterisation and properties of amino acid terminated dendrimer wedges

Staples, Robert Mark

January 1997

The rising demand for speciality polymers that possess novel properties has led to an interest in the tailored synthesis of dendritic polymers having highly controlled molecular architectures. Control over size, shape, molecular weight and functionality at the periphery of the molecule was used to design a series of dendrimer wedges with the ultimate aim of enhanced binding of a functional, property modifying unit to a cotton surface in water. Poly (propyleneimine) dendrimer wedges with various foci were produced in a stepwise way via a repetitive reaction sequence using the divergent approach. Initially, long chain aliphatic amines were used as starting materials and optimisation of the reaction conditions produced wedges up to the third generation possessing eight primary amine end groups. Subsequently dendrimer wedges were synthesised from a siloxysilane core up to the second generation. End group modification with amino acid residues was performed at the periphery of the wedges and adsorption studies were carried out to ascertain if enhanced molecular recognition at a cotton surface occurred. Also an investigation of the modification of polar surfaces by amine terminated dendrimers with a siloxysilane unit at the focus was performed.

547

Dendritic polymers

The synthesis and characterisation of aromatic hyperbranched polyesters

Keeney, Angela J.

January 1999

No description available.

547

Dendritic polymers; Cyclised polymers

Arborescent Copolymers: Synthesis, Properties & Metallic Nanoparticle Templating

Dockendorff, Jason Matthew

22 August 2011

Graft copolymers with a dendritic (arborescent) architecture and unimolecular micelle properties have been synthesized and examined for their solution properties as well as their ability to serve as templates for the preparation of metallic nanoparticles. The research focused on two types of arborescent copolymers, namely core-shell (CS) and core-shell-corona (CSC) architectures. Copolymer amphipolarity was provided by a hydrophobic polystyrene (PS) component and a polar poly(2-vinylpyridine), P2VP, phase. The CS copolymers were obtained by grafting P2VP onto linear or branched PS substrates to yield PS-g-P2VP unimolecular micelles. These copolymers exhibited solubility with limited aggregation in aqueous environments after protonation with HCl. Coordination of the coronal P2VP phase with HAuCl4 was achieved, and the resulting polymer-stabilized metallic nanoparticles had a spherical morphology. The tri-layered copolymers were synthesized in similar fashion, by grafting PS-b-P2VP block copolymers onto linear or branched PS substrates to afford a CSC morphology with a PS core, a P2VP inner shell, and a PS corona. While the grafting reaction proceeded with lower than expected grafting yields as compared to grafting reactions of homopolymer side-chains, significant P2VP content and molecular weight increases were achieved. It was determined that aggregation of the block copolymer side-chains hindered the coupling reaction of the reactive centers with the substrate. After purification of the PS-g-(P2VP-b-PS) arborescent copolymers, in part by developing a cloud-point centrifugation purification technique, the spherical copolymers were successfully loaded with various metallic compounds. The uptake of compounds such as HAuCl4 by the P2VP phase of the copolymers induced intramolecular phase segregation for copolymers of generations (G) 2 and above. Phase segregation produced some unique and intricate morphologies different from the ones observed previously for other unimolecular metal scaffolds. Intramolecular toroidal, nodular, and cylindrical morphologies were observed for the G2, G3, and G4 arborescent copolymers, respectively. Templates of generations 0 and 1 displayed a spherical morphology similar to their PS-b-P2VP intermolecular micelle analogues when loaded with metals. Phase segregation is believed to be mediated mainly by the characteristics of the PS core, the length of the P2VP segments having less influence on the morphologies obtained. Reduction of the metallic salts was performed using various agents and protocols. Stronger reducing agents yielded smaller and more narrowly distributed gold nanoparticles, while other reduction methods also removing the polymer scaffold resulted in larger nanoparticles.

arborescent polymer

polymer chemistry

branched polymers

dendritic polymers

unimolecular micelle

nanoparticle template

polymer morphology

polymer phase segregation

Chemistry

Arborescent Copolymers: Synthesis, Properties & Metallic Nanoparticle Templating

Dockendorff, Jason Matthew

22 August 2011

Graft copolymers with a dendritic (arborescent) architecture and unimolecular micelle properties have been synthesized and examined for their solution properties as well as their ability to serve as templates for the preparation of metallic nanoparticles. The research focused on two types of arborescent copolymers, namely core-shell (CS) and core-shell-corona (CSC) architectures. Copolymer amphipolarity was provided by a hydrophobic polystyrene (PS) component and a polar poly(2-vinylpyridine), P2VP, phase. The CS copolymers were obtained by grafting P2VP onto linear or branched PS substrates to yield PS-g-P2VP unimolecular micelles. These copolymers exhibited solubility with limited aggregation in aqueous environments after protonation with HCl. Coordination of the coronal P2VP phase with HAuCl4 was achieved, and the resulting polymer-stabilized metallic nanoparticles had a spherical morphology. The tri-layered copolymers were synthesized in similar fashion, by grafting PS-b-P2VP block copolymers onto linear or branched PS substrates to afford a CSC morphology with a PS core, a P2VP inner shell, and a PS corona. While the grafting reaction proceeded with lower than expected grafting yields as compared to grafting reactions of homopolymer side-chains, significant P2VP content and molecular weight increases were achieved. It was determined that aggregation of the block copolymer side-chains hindered the coupling reaction of the reactive centers with the substrate. After purification of the PS-g-(P2VP-b-PS) arborescent copolymers, in part by developing a cloud-point centrifugation purification technique, the spherical copolymers were successfully loaded with various metallic compounds. The uptake of compounds such as HAuCl4 by the P2VP phase of the copolymers induced intramolecular phase segregation for copolymers of generations (G) 2 and above. Phase segregation produced some unique and intricate morphologies different from the ones observed previously for other unimolecular metal scaffolds. Intramolecular toroidal, nodular, and cylindrical morphologies were observed for the G2, G3, and G4 arborescent copolymers, respectively. Templates of generations 0 and 1 displayed a spherical morphology similar to their PS-b-P2VP intermolecular micelle analogues when loaded with metals. Phase segregation is believed to be mediated mainly by the characteristics of the PS core, the length of the P2VP segments having less influence on the morphologies obtained. Reduction of the metallic salts was performed using various agents and protocols. Stronger reducing agents yielded smaller and more narrowly distributed gold nanoparticles, while other reduction methods also removing the polymer scaffold resulted in larger nanoparticles.

arborescent polymer

polymer chemistry

branched polymers

dendritic polymers

unimolecular micelle

nanoparticle template

polymer morphology

polymer phase segregation

Chemistry

Synthesis and Characterization of Poly(arylene ether sulfone)s with Novel Structures and Architectures

Osano, Keiichi

21 May 2009

Poly(arylene ether sulfone)s with dendritic terminal groups were synthesized by step-growth polymerization of two difunctional monomers in the presence of preformed dendritic end-cappers. These polymers were characterized by NMR, SEC, DSC, TGA, melt rheology and tensile tests. The melt viscosities of these polymers in the high frequency region were lower than the control while the stress-strain properties were comparable to those of the control, suggesting that it is possible to reduce the high shear melt viscosities of this type of polymers without affecting the stress-strain properties by introducing bulky dendritic terminal groups. Poly(arylene ether sulfone)s with hyperbranched terminal groups were also synthesized. These polymers were synthesized by reacting fluoro-terminated poly(arylene ether sulfone) chains with an arylene ether ketone AB2 monomer. The terminal groups of these polymers were capped by tert-butylphenol. The results from NMR and SEC showed that multiple tert-butyl units were successfully introduced onto the polymer chains, suggesting that this synthetic method could be useful for introducing multiple functional groups onto the polymer chain ends in fewer synthetic steps than an analogous method using preformed dendritic end-cappers. It was also demonstrated that multiple sulfonated phenols were attached to the terminal groups of polysulfones by this method. A novel cyclohexyl-containing difunctional monomer was prepared and successfully incorporated into poly(arylene ether sulfone) backbones. These polymers were characterized by NMR, SEC, DSC, TGA, DMA and tensile tests and compared to terephthaloyl analogs. Tensile tests and DMA showed the cyclohexyl units impart a higher magnitude of secondary relaxation than the terephthaloyl units while maintaining high modulus, suggesting that these polymers may have higher impact strength than the ones with no cyclohexyl units. / Ph. D.

structure-property relationship

dendritic polymers

linear-dendritic copolymers

poly(arylene ether sulfone)s

poly(arylene ether ketone)s