[ { "name": "Khabiboulline, Emil Timergalievich", "degree": "Senior Thesis", "year": "2016", "title": "Angle-Resolved Mid-Infrared Spectroscopy of Gyroid Photonic Crystals", "advisor": "Unknown, Unknown", "url": "https://resolver.caltech.edu/CaltechTHESIS:01102018-102454651", "creators": [ { "name": { "family": "Khabiboulline", "given": "Emil Timergalievich" }, "id": "Khabiboulline-Emil-Timergalievich", "orcid": "0000-0001-9151 -6464", "display_name": "Khabiboulline, Emil Timergalievich" } ], "advisors": [ { "name": { "family": "Unknown", "given": "Unknown" }, "display_name": "Unknown, Unknown" } ], "committee": [ { "name": { "family": "None", "given": "None" }, "display_name": "None, None" } ], "option_major": [ "physics" ], "doi": "10.7907/4GR6-3646", "abstract": "Gyroid photonic crystals, which can form photonic topological insulators, offer a rich\r\ndiversity of physics for fundamental study, in addition to yielding useful applications.\r\nUnderstanding their band structure is crucial towards advancing both fronts. An\r\nangle-resolved spectroscopy apparatus is constructed to experimentally measure\r\nband structures. Operating at wavelengths from 7.7 to 11.1 \u03bcm, it is employed to\r\nstudy single and double-gyroid photonic crystals, constructed of amorphous silicon\r\nin 5 \u03bcm unit cells. Transmittance and reflectance act as indicators of density of\r\nstates, and are collected as spectra over angles of incidence ranging from 17 to 30\r\ndegrees. Comparison to theory confirms interesting features, such as bandgaps.\r\nFurther simulation guides the design of a crystal amenable to the first experimental\r\nmeasurement of Weyl points at mid-infrared wavelengths." }, { "name": "Latawiec, Pawel Michal", "degree": "Senior Thesis", "year": "2013", "title": "Bandgap Engineering Silicon Nanopillars", "advisor": "Scherer, Axel", "url": "https://resolver.caltech.edu/CaltechTHESIS:02132018-124953265", "creators": [ { "name": { "family": "Latawiec", "given": "Pawel Michal" }, "id": "Latawiec-Pawel-Michal", "display_name": "Latawiec, Pawel Michal" } ], "advisors": [ { "name": { "family": "Scherer", "given": "Axel" }, "id": "Scherer-A", "role": "advisor", "display_name": "Scherer, Axel" } ], "committee": [ { "name": { "family": "None", "given": "None" }, "display_name": "None, None" } ], "option_major": [ "physics" ], "doi": "10.7907/CNP5-BZ88", "abstract": "Vertically oriented , bandgap engineered silicon nanopillars were fabricated and addressed. Devices were fabricated via a three dimensional etching process which created sub-5 nm constrictions in silicon radius upon oxidation. This effect was used to create a Coulomb blockade device. Devices were tested at room and liquid nitrogen temperatures. They showed a clear blockade effect distinctive of an asymmetric double tunnel junction at low temperatures which disappeared when tested at higher temperatures. Different device fabrication parameters were also tested to develop high-current devices, including chip anneal time. Furthermore, both device fabrication steps and current flow were modeled and simulated." }, { "name": "Moehle, Austin Michael", "degree": "Senior Thesis", "year": "2012", "title": "Effects of Ca-Doping on the Vortex Properties and Pairing Symmetry of (Y1-xCax)Ba2Cu3O7-\u03b4", "advisor": "Yeh, Nai-Chang", "url": "https://resolver.caltech.edu/CaltechTHESIS:02132018-143120671", "creators": [ { "name": { "family": "Moehle", "given": "Austin Michael" }, "id": "Moehle-Austin-Michael", "display_name": "Moehle, Austin Michael" } ], "advisors": [ { "name": { "family": "Yeh", "given": "Nai-Chang" }, "id": "Yeh-Nai-Chang", "orcid": "0000-0002-1826-419X", "role": "advisor", "display_name": "Yeh, Nai-Chang" } ], "committee": [ { "name": { "family": "None", "given": "None" }, "display_name": "None, None" } ], "option_major": [ "physics" ], "doi": "10.7907/Y3T0-N679", "abstract": "N/A" } ]