Browsing by Subject "Template stripping"
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Item Design, Characterization, and Manufacturing of Ultra-sharp Metallic Probes for Near-field Optics(2014-05) Johnson, TimothyThe ability to manipulate and nanofocus light has many potential applications such as surface-enhanced spectroscopy, optical trapping, heat-assisted magnetic recording, and near-field imaging. In this thesis a new method to fabricate devices for nanofocusing is introduced and then demonstrated for use in near-field imaging. This method uses a sharp, metallic tip to confine and focus the light. Current methods to produce these sharp tips suffer from low reliability and low-throughput processing methods. Here a fabrication method called template stripping is introduced. With this method, precise control over the fabrication of metal films with integrated bumps, grooves, and holes is shown. Next, the method is used to fabricate sharp, metallic tips. The tips are used for near-field imaging and show a resolution of < 20 nm and observed fluorescence enhancements of ~200x from single fluorescent molecules. The tips are also demonstrated for near-field Raman imaging of carbon nanotube bundles and show good results. These tips provide high-quality results, but one of the more important features is that the yield of the tips is around 95%, much higher than current methods for fabricating sharp, metallic tips. Also, different schemes to create nanofocusing are presented. One method makes use of an asymmetric metal deposition and another a C-shaped aperture around the tip to focus light illuminating the tip from inside itself. Both of these methods show significant nanofocusing and provide new structures for nanofocusing studies. The processes to fabricate these structures are developed with the hope that they will be widely disseminated to allow more researchers access to reliable tips and hopefully bringing more people into the field of near-field imaging.Item Template-stripped plasmonic cup resonators for single-nanohole-based sensing and spectroscopy(2015-05) Olson, Stephen Andrew OlafWe have designed and tested a new plasmonic biosensor, featuring a centered nanohole in the base of a recessed metallic nanocup. This configuration enables us to perform independent plasmon-resonance-enhanced single-nanohole transmission spectroscopy on femtoliter volumes of solution. In this thesis we will demonstrate the fabrication, characterization, and application of these novel cup resonator plasmonic biosensors. Utilizing plasmonic confinement to enhance and modulate transmission through a nanohole aperture, the resulting transmission spectra can be used to determine changes in the material properties of a dielectric material located inside the sensing volume of the cup. We have determined, through measurements and simulations, the physical mechanisms causing transmission modulation through the structure. Utilizing this information, we have constructed predictive behavior models for the design and customization of these devices for specific purposes. We show that these structures are responsive to refractive index changes in their surroundings, and propose some possible application of these resonators in biological sensing roles which take advantage of their unique geometry.