Your search keyword '"Spiess, Hans W."' showing total 6 results

1. EPR spectroscopic characterization of local nanoscopic heterogeneities during the thermal collapse of thermoresponsive dendronized polymers.

Author

Junk MJ, Li W, Schlüter AD, Wegner G, Spiess HW, Zhang A, and Hinderberger D

Subjects

Electron Spin Resonance Spectroscopy, Nanostructures chemistry, Phase Transition, Temperature, Thermodynamics, Anthracenes chemistry, Polymers chemistry

Published

2010

2. Anhydrous proton-conducting properties of triazole-phosphonic acid copolymers: a combined study with MAS NMR.

Author

Celik SU, Akbey U, Graf R, Bozkurt A, and Spiess HW

Subjects

Carbon Isotopes, Electric Conductivity, Electrolytes chemical synthesis, Electrolytes chemistry, Hydrogen Bonding, Magnetic Resonance Spectroscopy standards, Molecular Structure, Molecular Weight, Phosphorus Isotopes, Polymers chemical synthesis, Reference Standards, Temperature, Magnetic Resonance Spectroscopy methods, Organophosphonates chemistry, Polymers chemistry, Protons, Triazoles chemistry, Vinyl Compounds chemistry

Abstract

The synthesis, thermal and proton conducting properties of copolymers based on vinylphosphonic acid (VPA) and 1-vinyl-1,2,4-triazole (VTri) were investigated. The copolymers were synthesized by free-radical copolymerization of the corresponding monomers at several monomer feed ratios to obtain poly(VPA-co-VTri) copolymer electrolytes. The final structures of the copolymers were confirmed by spectroscopic methods. The composition of the low molecular weight copolymers was varied with the feed ratio of the monomers. The presence of triazole units in the copolymers suppresses the formation of phosphonic acid anhydrides up to 150 degrees C, as verified by both (31)P NMR and TGA. The observation of defined glass transition temperatures indicated that the ionic interactions do not prevent segmental relaxations of the polymer chains. In the absence of humidity, the copolymer electrolyte, poly(VPA-co-VTri), S2 (with 33% triazole content) showed proton conductivity of 10(-3) S cm(-1) at 120 degrees C, which is far higher than in imidazole based copolymers. Two different types of hydrogen-bonded protons were detected by (1)H MAS NMR in the solid copolymer systems, due to different arrangements of triazole and phosphonic acid units.

Published

2008

3. Heterogeneity in polymer melts from melting of polymer crystals.

Author

Rastogi, Sanjay, Lippits, Dirk R., Peters, Gerrit W. M., Graf, Robert, Yao, Yefeng, and Spiess, Hans W.

Subjects

POLYMERS

Abstract

A correction to the article "Heterogeneity in polymer melts from melting of polymer crystals," that was published in the June 22, 2005 issue is presented.

Published

2006

4. Formation of a Mesoscopic Skin Barrier in Mesoglobules of Thermoresponsive Polymers.

Author

Junk, Matthias J. N., Wen Li, Schlüter, A. Dieter, Wegner, Gerhard, Spiess, Hans W., Afang Zhang, and Hinderberger, Dariush

Subjects

*ELECTRON paramagnetic resonance, *SPECTRUM analysis, *POLYMERS, *MOLECULES, *DENDRIMERS, *BIOCHEMISTRY

Abstract

With the combination of molecular scale information from electron paramagnetic resonance (EPR) spectroscopy and meso-/macroscopic information from various other characterization techniques, the formation of mesoglobules of thermoresponsive dendronized polymers is explained. Apparent differences in the EPR spectra in dependence of the heating rate, the chemical nature of the dendritic substructure of the polymer, and the concentration are interpreted to be caused by the formation of a dense polymeric layer at the periphery of the mesoglobule. This skin barrier is formed in a narrow temperature range of ∼4 K above TC and prohibits the release of molecules that are incorporated in the polymer aggregate. In large mesoglobules, formed at low heating rates and at high polymer concentrations, a considerable amount of water is entrapped that microphase-separates from the collapsed polymer chains at high temperatures. This results in the aggregates possessing an aqueous core and a corona consisting of collapsed polymer chains. A fast heating rate, a low polymer concentration, and hydrophobic subunits in the dendritic polymer side chains make the entrapment of water less favorable and lead to a higher degree of vitrification. This may bear consequences for the design and use of thermoresponsive polymeric systems in the fast growing field of drug delivery. [ABSTRACT FROM AUTHOR]

Published

2011

5. Self-Assembly of Dendronized Triphenylenes Into Helical Pyramidal Columns and Chiral Spheres.

Author

Percec, Virgil, Imam, Mohammad R., Peterca, Mihai, Wilson, Daniela A., Graf, Robert, Spiess, Hans W., Balagurusamy, Venkatachalapathy S. K., and Heiney, Paul A.

Subjects

*CHIRALITY, *POLYMERS, *MOLECULES, *ORGANIC compounds, *CHEMISTRY

Abstract

The synthesis and structural and retrostructural analyses of a library containing 10 triphenylenes functionalized with self-assembling benzyl ether and phenyl propyl ether dendrons are reported. These dendronized triphenylenes adopt a crown rather than discotic information. Their crown conformation mediates the self-assembly of the discotic triphenylene unit in helical pyramidal columns and in chiral spheres. The chiral spheres are generated from short segments of helical pyramidal columns that are spherically distorted. Therefore, the chirality of the sphere is determined by a short helical pyramidal column that represents the inner part of the supramolecular sphere. Both the helical pyramidal columns and the chiral spheres represent supramolecular architectures that were self-assembled for the first time from discotic molecules. The helical pyramidal columns self-organize in various hexagonal and rectangular lattices, while the chiral spheres self-organize into cubic and tetragonal periodic arrays and into a quasiperiodic 12-fold liquid quasicrystal. The helical sense of the helical pyramidal columns and of helical spheres is selected by a stereocenter that can be incorporated either in the alkyl groups of the dendron or in the triphenylene part of the dendritic crown via donor-acceptor interactions. The self-assembly process of the dendronized triphenylene donor can be programmed by a new supramolecular "polymer effect" generated by donor-acceptor interactions. [ABSTRACT FROM AUTHOR]

Published

2009

6. Ring-Expansion Metathesis Polymerization: Catalyst-Dependent Polymerization Profiles.

Author

Xia, Yan, Boydston, Andrew J., Yao, Yefeng, Kornfield, Julia A., Gorodetskaya, Irma A., Spiess, Hans W., and Grubbs, Robert H.

Subjects

*METATHESIS reactions, *CATALYSTS, *POLYMERIZATION, *POLYMERS, *MOLECULAR weights, *TOPOLOGY

Abstract

Ring-expansion metathesis polymerization (REMP) mediated by recently developed cyclic Ru catalysts has been studied in detail with a focus on the polymer products obtained under varied reaction conditions and catalyst architectures. Depending upon the nature of the catalyst structure, two distinct molecular weight evolutions were observed. Polymerization conducted with catalysts bearing six-carbon tethers displayed rapid polymer molecular weight growth which reached a maximum value at Ca. 70% monomer conversion, resembling a chain-growth polymerization mechanism. In contrast, five-carbon- tethered catalysts led to molecular weight growth that resembled a step-growth mechanism with a steep increase occurring only after 95% monomer conversion. The underlying reason for these mechanistic differences appeared to be ready release of five-carbon-tethered catalysts from growing polymer rings, which competed significantly with propagation. Owing to reversible chain transfer and the lack of end groups in REMP, the final molecular weights of cyclic polymers was controlled by thermodynamic equilibria. Large ring sizes in the range of 60-120 kDa were observed at equilibrium for polycyclooctene and polycyclododecatriene, which were found to be independent of catalyst structure and initial monomer/catalyst ratio. While six-carbon-tethered catalysts were slowly incorporated into the formed cyclic polymer, the incorporation of five-carbon-tethered catalysts was minimal, as revealed by ICP-MS. Further polymer analysis was conducted using melt-state magic-angle spinning 13C NMR spectroscopy of both linear and cyclic polymers, which revealed little or no chain ends for the latter topology. [ABSTRACT FROM AUTHOR]

Published

2009