Engineering Commons^™

Microfluidically Reconfigurable Millimeter-Wave Switches, Antenna Arrays And Filters With Fast-Actuation Using Movable Metallized Plates And Integrated Actuation, Enrique J. Gonzalez Carvajal

USF Tampa Graduate Theses and Dissertations

Microfluidic reconfiguration of microwave devices has emerged as a potentially attractive alternative to integrated semiconductor (ICs/MMICs) and microelectromechanical systems (MEMS) based technologies. On the one hand, MMICs suffer from low power handling capabilities, high IL, non-linear effects, and elevated costs; on the other hand, MEMS are limited by their complex packaging requirements, and relatively low reliability from stiction-based effects. However, microfluidic reconfiguration provides low insertion loss (IL) due to its mechanical nature and it is not limited by power saturation effects. These attributes are especially valuable for applications at mm-waves, potentially reducing costs and increasing power efficiency capabilities. Microfluidic reconfiguration …

Zno Nanostructures: Growth, Characterization And Applications, Mikhail Ladanov

USF Tampa Graduate Theses and Dissertations

ZnO nanostructures have been investigated for quite a long time. However, only recently they triggered much interest due to advances in materials synthesis and characterization, as well as emerging demand for new nanostructured materials in novel device implementations.

A large part of the work was devoted to exploring new methodology for patterning growth sites and controlling nanowires morphology using the deposition methods that are compatible with integrated circuits (IC) processing. Microcontact printing was used to pattern the seeding layer, and, subsequently, ZnO nanowires through a resistless soft lithography process.

When considering hydrothermal growth of ZnO nanowires in the framework of …

Optimization Of Bio-Impedance Sensor For Enhanced Detection And Characterization Of Adherent Cells, Dorielle T. Price

USF Tampa Graduate Theses and Dissertations

This research focuses on the detection and characterization of cells using

impedance-based techniques to understand the behavior and response of cells to internal/environmental changes. In combination with impedimetric sensing techniques, the biosensors in this work allow rapid, label-free, quantitative measurements and are very sensitive to changes in environment and cell morphology. The biosensor design and measurement setup is optimized to detect and differentiate cancer cells and healthy (normal) cells. The outcome of this work will provide a foundation for enhanced 3-dimensional tumor analysis and characterization; thus creating an avenue for earlier cancer detection and reduced healthcare costs.

The magnitude of …