Graduation Semester and Year
2019
Language
English
Document Type
Dissertation
Degree Name
Doctor of Philosophy in Electrical Engineering
Department
Electrical Engineering
First Advisor
Michael Vasilyev
Abstract
Silicon Nitride (SiN) is a CMOS compatible optical material that can be used for both linear and nonlinear optics applications. SiN has high refractive index (1.99-2.0) and low two photon absorption (TPA) coefficient. As a result, SiN can be used as a core material to guide and bend light, and the development of compact on-chip SiN optical devices exploiting both linear and nonlinear optical phenomena is very much feasible. In this thesis work, two independent research projects are presented. The first work presents the design of a hybrid SiN/Polymer slot waveguide for second-harmonic generation (SHG) of a 1550-nm wave at 775 nm. This is a simulation-based work where the waveguide dimensions are numerically optimized to fulfill the conditions required for SHG in a bended structure, i.e. microring. This work presents an optimum slot waveguide design with very high effective nonlinearity, with a critical slot dimension of 200 nm that is very much attainable in a class 100 cleanroom facility like Shimadzu Institute- Nanotechnology Research Center, University of Texas at Arlington and shows prospect of developing waveguide and micro-resonator based nonlinear photonic integrated circuits. In the second project, a microring resonator has been designed, fabricated and characterized for biosensing applications. The fabrication steps are discussed thoroughly so that it can be replicated in future research endeavors. This fabricated optical biosensor has been designed to work in aqueous environment, so that the presence of particular biomaterial, in this case Neuropeptide Y (NPY), can be easily detected and quantified according to sample concentration at µg/ml level. The experimental investigations confirm that the detection limit of this microring resonator in a single assay system is 1 µg/ml with a sensitivity of 0.1 nm/(µg/ml). This sensitivity can be amplified by a factor of 3 by using sandwiched assay system, and NPY concentration at 0.25 µg/ml level was successfully detected.
Keywords
Nonlinear optics, Second harmonic generation, Silicon nitride waveguide, Slot waveguide, Neuropeptide Y, Refractive index sensor, Micro-ring resonator
Disciplines
Electrical and Computer Engineering | Engineering
License
This work is licensed under a Creative Commons Attribution-NonCommercial-Share Alike 4.0 International License.
Recommended Citation
Das, Subrata, "Nonlinear Optics and Bio-sensing with Silicon Nitride Waveguides" (2019). Electrical Engineering Dissertations. 300.
https://mavmatrix.uta.edu/electricaleng_dissertations/300
Comments
Degree granted by The University of Texas at Arlington