Structural Characterization of Polymer-Clay Nanocomposites Prepared by Co-Precipitation Using EPR Techniques.

Polymer-clay nanocomposites (PCNCs) containing either a rubber or an acrylate polymer were prepared by drying or co-precipitating polymer latex and nanolayered clay (synthetic and natural) suspensions. The interface between the polymer and the clay nanoparticles was studied by electron paramagnetic resonance (EPR) techniques by selectively addressing spin probes either to the surfactant layer (labeled stearic acid) or the clay surface (labeled catamine). Continuous-wave (CW) EPR studies of the surfactant dynamics allow to define a transition temperature T* which was tentatively assigned to the order-disorder transition of the surfactant layer. CW EPR studies of PCNC showed that completely exfoliated nanoparticles coexist with agglomerates. HYSCORE spectroscopy in PCNCs showed couplings within the probe -assigned with DFT computations- and couplings with nuclei of the environment, ¹H and 23Na for the surfactant layer probe, and 29Si, 7Li, 19F and 23Na for the clay surface probe. Analysis of these couplings indicates that the integrity of the surfactant layer is conserved and that there are sizeable ionic regions containing sodium ions directly beyond the surfactant layer. Simulations of the very weak couplings demonstrated that the HYSCORE spectra are sensitive to the composition of the clay and whether or not clay platelets stack.

Visualizing the self-assembly of tubulin with luminescent nanorods.

We succeeded in labeling tubulin with luminescent CdSe nanorods. The labeled tubulin was still able to self-assemble into microtubules, demonstrating that the protein has remained functional. The comparison with rhodamine-labeled tubulin revealed that whereas the rhodamine bleached completely within the observed time frame, the nanorods did not show any bleaching, which makes it possible to follow the key events of self-assembly at high time resolution. Preparation and derivatization of nanorods are described. Water-soluble, protein-reactive group-containing particles were covalently coupled to tubulin. The conjugate was purified by one cycle of assembly and disassembly and used to induce the formation of fluorescent microtubules. These results suggest that the use of luminescent nanorods should allow continuous confocal monitoring of dynamic biological processes.

Electrochemical metallization of self-assembled porphyrin monolayers.

Multifunctional sensor systems are becoming increasingly important in electroanalytical chemistry. Together with ongoing miniaturization there is a need for micro- and nanopatterning tools for thin electroactive layers (e.g. self-assembling monolayers). This paper documents a method for production of a micro-array of different metal-porphyrin monolayers with different sensor properties. A new method has been developed for the selective and local metallization of bare porphyrin monolayers by cathodic pulsing and sweeping. The metal-porphyrin monolayers obtained were characterized by cyclic voltammetry. It was shown that porphyrin monolayers can be metallized with manganese, iron, cobalt, and nickel by use of the new method. It is expected that all types of metal-porphyrin monolayers can be produced in the same manner.