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Hybrid nanomaterials offer the combination of individual properties of different types of nanoparticles. Some strategies for the development of new nanostructures in larger scale rely on the self-assembly of nanoparticles as a bottom-up approach. The use of templates provides ordered assemblies in defined patterns. In a typical soft-template, nanoparticles and other surface-active agents are incorporated into non-miscible liquids. The resulting self-organized dispersions will mediate nanoparticle interactions to control the subsequent self-assembly. Especially interactions between nanoparticles of very different dispersibility and functionality can be directed at a liquid-liquid interface.
In this project, water-in-oil microemulsions were formulated from quasi-ternary mixtures with Aerosol-OT as surfactant. Oleyl-capped superparamagnetic iron oxide and/or silver nanoparticles were incorporated in the continuous organic phase, while polyethyleneimine-stabilized gold nanoparticles were confined in the dispersed water droplets. Each type of nanoparticle can modulate the surfactant film and the inter-droplet interactions in diverse ways, and their combination causes synergistic effects. Interfacial assemblies of nanoparticles resulted after phase-separation. On one hand, from a biphasic Winsor type II system at low surfactant concentration, drop-casting of the upper phase afforded thin films of ordered nanoparticles in filament-like networks. Detailed characterization proved that this templated assembly over a surface is based on the controlled clustering of nanoparticles and the elongation of the microemulsion droplets. This process offers versatility to use different nanoparticle compositions by keeping the surface functionalization, in different solvents and over different surfaces. On the other hand, a magnetic heterocoagulate was formed at higher surfactant concentration, whose phase-transfer from oleic acid to water was possible with another auxiliary surfactant in ethanol-water mixture. When the original components were initially mixed under heating, defined oil-in-water, magnetic-responsive nanostructures were obtained, consisting on water-dispersible nanoparticle domains embedded by a matrix-shell of oil-dispersible nanoparticles.
Herein, two different approaches were demonstrated to form diverse hybrid nanostructures from reverse microemulsions as self-organized dispersions of the same components. This shows that microemulsions are versatile soft-templates not only for the synthesis of nanoparticles, but also for their self-assembly, which suggest new approaches towards the production of new sophisticated nanomaterials in larger scale.
This thesis deals with the synthesis of protein and composite protein-mineral microcapsules by the application of high-intensity ultrasound at the oil-water interface. While one system is stabilized by BSA molecules, the other system is stabilized by different nanoparticles modified with BSA. A comprehensive study of all synthesis stages as well as of resulting capsules were carried out and a plausible explanation of the capsule formation mechanism was proposed. During the formation of BSA microcapsules, the protein molecules adsorb firstly at the O/W interface and unfold there forming an interfacial network stabilized by hydrophobic interactions and hydrogen bonds between neighboring molecules. Simultaneously, the ultrasonic treatment causes the cross-linking of the BSA molecules via the formation of intermolecular disulfide bonds. In this thesis, the experimental evidences of ultrasonically induced cross-linking of the BSA in the shells of protein-based microcapsules are demonstrated. Therefore, the concept proposed many years ago by Suslick and co-workers is confirmed by experimental evidences for the first time. Moreover, a consistent mechanism for the formation of intermolecular disulfide bonds in capsule shells is proposed that is based on the redistribution of thiol and disulfide groups in BSA under the action of high-energy ultrasound. The formation of composite protein-mineral microcapsules loaded with three different oils and shells composed of nanoparticles was also successful. The nature of the loaded oil and the type of nanoparticles in the shell, had influence on size and shape of the microcapsules. The examination of the composite capsule revealed that the BSA molecules adsorbed on the nanoparticles surface in the capsule shell are not cross-linked by intermolecular disulfide bonds. Instead, a Pickering emulsion formation takes place. The surface modification of composite microcapsules through both pre-modification of main components and also the post-modification of the surface of ready composite microcapsules was successfully demonstrated. Additionally, the mechanical properties of protein and composite protein-mineral microcapsules were compared. The results showed that the protein microcapsules are more resistant to elastic deformation.