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The goal of this research is to produce highly tailored nanocomposite ( plastic ) products; herein, an attempt to understand the entropic and enthalpic forces that govern the dispersion and dissolution of nanoparticles in solutions and in thin polymer films is presented in this work. In the first part, neutron reflectivity was used to study the impact of nanoparticle presence on the surface segregation of deuterated polystyrene (dPS) in a polystyrene matrix. The impact of the presence of cylinders (carbon nanotubes), sheets (graphene), and spheres (polystyrene soft nanoparticles) on the…mehr

Produktbeschreibung
The goal of this research is to produce highly tailored nanocomposite ( plastic ) products; herein, an attempt to understand the entropic and enthalpic forces that govern the dispersion and dissolution of nanoparticles in solutions and in thin polymer films is presented in this work. In the first part, neutron reflectivity was used to study the impact of nanoparticle presence on the surface segregation of deuterated polystyrene (dPS) in a polystyrene matrix. The impact of the presence of cylinders (carbon nanotubes), sheets (graphene), and spheres (polystyrene soft nanoparticles) on the surface segregation process and ultimate structure were examined. The next part focuses on developing a protocol using static light scattering and refractometry to quantitatively determine the solubility behavior of boron containing nanoparticles. With scattering, the second virial coefficient is obtained and used to calculate the solute-solvent interaction parameter, [chi], which quantifies the mixing behavior. Finally, two purification techniques for SWNTs, acid purification and purification via centrifugation in surfactant, were examined.
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Autorenporträt
The work presented in this text is her key research leading to the doctoral degree. Most notably, Dr. Mutz is likely the first researcher to measure the refractive index increment of nanoparticle dispersions (boron nitride nanotubes and single walled carbon nanotubes), using a Brice Phoenix Refractometer ¿ an important factor for materials design.