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Title page for ETD etd-06032013-122649


Type of Document Master's Thesis
Author Garnett, Joy Carleen
Author's Email Address joy.garnett@vanderbilt.edu
URN etd-06032013-122649
Title Maxwell Fisheye Lens As A Waveguide Crossing For Integrated Photonics
Degree Master of Science
Department Interdisciplinary Materials Science
Advisory Committee
Advisor Name Title
Dr. Jason Valentine Committee Co-Chair
Dr. Norman Tolk Committee Co-Chair
Keywords
  • integrated optics
  • Maxwell Fisheye
  • gradient optics
  • metamaterials
  • gradient lens
Date of Defense 2013-06-30
Availability unrestricted
Abstract
Integrated silicon (Si) photonics represents one of the key technologies for developing compact high speed optical systems for computing and telecommunications. In such systems, electric buses are replaced with integrated Si waveguides which transport light across the chip. In order to implement high density networks, it is inevitable that waveguides will need to be crossed to transport information across orthogonal directions. However, when two or more waveguides cross, light is scattered due to the abrupt change in the modal index resulting in losses of up to 40 percent. This loss occurs to both the environment as well as the overlapped waveguide, causing cross-talk into the other channel resulting in false signals.

Current Si based waveguide crosses require either a large footprint or are limited in the number of waveguides that can be crossed simultaneously. In this work, we develop integrated gradient index elements based on the Maxwell Fisheye (MFE) to provide low-loss and massively parallel optical waveguide crossings. To realize a crossing, waveguides which are modal index matched to the MFE are coupled across the lens wherein the output of one waveguide is imaged to the input of its partner on the opposite side. Based on this methodology, we present full-wave modeling of the device demonstrating a 0.1 dB loss (97.7% transmission) per

crossing for an overall waveguide cross footprint of 28.26 square microns, among the most efficient designs to date. We also propose how this device can be realized using smoothly tapered Si waveguides to provide

the required 2D gradient refractive index profile.

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