Return to search

Fabrication and testing of nano-optical structures for advanced photonics and quantum information processing applications

Interest in the fabrication of nano-optical structures has increased dramatically
in recent years, due to advances in lithographic resolution. In particular, metallic
nanostructures are of interest because of their ability to concentrate light to well
below the diffraction limit. Such structures have many potential applications, including nanoscale photonics, quantum information processing and single molecule
detection/imaging. In the case of quantum computing and quantum communication,
plasmon-based metal nanostructures offer the promise of scalable devices. This is because the small optical mode volumes of such structures give the large atom-photon
coupling needed to interface solid-state quantum bits (qubits) to photons. The main
focus of this dissertation is on fabrication and testing of surface plasmon-based metal
nanostructures that can be used as optical wires for effciently collecting and directing an isolated atom or molecule's emission. In this work, Ag waveguides having
100nm£50nm and 50nm£50nm cross sections have been fabricated ranging from 5¹m
to 16¹m in length. Different types of coupling structures have also been fabricated to
allow in-coupling and out-coupling of free space light into and out of the nanometric
waveguides. The design of waveguides and couplers have been accomplished using a
commercial finite difference in time domain (FDTD) software. Different nanofabrication techniques and methods have been investigated leading to robust and reliable
process conditions suitable for very high aspect ratio fabrication of metal structures. Detailed testing and characterization of the plasmon based metal waveguides and couplers have also been carried out. Test results have revealed effective surface plasmon
propagation range. 0.5dB/¹m and 0.07dB/¹m transmission losses have been found
for 100nm and 50nm wide waveguides respectively, which correspond to 1/e propagation lengths of 9¹m and 60¹m. Input coupling effciency was found to be 2% and
output coupling effciency was found to be 35%. The fabrication and testing results
presented provide critical demonstrations to establish the feasibility of nanophotonic
integrated circuits, scalable quantum information processing devices, as well as other
devices, such as single molecule detectors and imaging systems.

Identiferoai:union.ndltd.org:tamu.edu/oai:repository.tamu.edu:1969.1/ETD-TAMU-1165
Date15 May 2009
CreatorsKhan, Mughees Mahmood
ContributorsHemmer, Philip R.
Source SetsTexas A and M University
Languageen_US
Detected LanguageEnglish
TypeBook, Thesis, Electronic Dissertation, text
Formatelectronic, application/pdf, born digital

Page generated in 0.0018 seconds