Selective oxidation of aluminum-bearing III-V semiconductors: Properties and applications to small-volume quantum well heterostructure lasers
Ries, Michael John
This item is only available for download by members of the University of Illinois community. Students, faculty, and staff at the U of I may log in with your NetID and password to view the item. If you are trying to access an Illinois-restricted dissertation or thesis, you can request a copy through your library's Inter-Library Loan office or purchase a copy directly from ProQuest.
Permalink
https://hdl.handle.net/2142/22399
Description
Title
Selective oxidation of aluminum-bearing III-V semiconductors: Properties and applications to small-volume quantum well heterostructure lasers
Author(s)
Ries, Michael John
Issue Date
1996
Doctoral Committee Chair(s)
Holonyak, Nick, Jr.
Department of Study
Electrical and Computer Engineering
Discipline
Electrical and Computer Engineering
Degree Granting Institution
University of Illinois at Urbana-Champaign
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
Engineering, Electronics and Electrical
Physics, Condensed Matter
Language
eng
Abstract
"In this work, the water-vapor oxidation of Al-bearing III-V compound semiconductors is used to fabricate small-volume semiconductor light-emitting devices. The oxidized material, native to the crystal, is mechanically and chemically stable. In addition, it is electrically insulating and has a low refractive index making it useful for defining optical cavities and current paths. The oxidation rate is sensitive to the Al composition of the material, permitting selective oxidation of ""buried"" high-Al-composition layers."
"The selective oxidation of ""buried"" layers is used in this work to fabricate laser cavities that are small in volume. Small-volume cavities, called microcavities, are known to exert control over the recombination of carriers within the cavity, and may be exploited to create devices with improved laser characteristics. In this work, the embedded oxide is used to form the distributed Bragg reflecting (DBR) mirrors of a vertical-cavity surface-emitting laser (VCSEL), resulting in a very high index-contrast mirror and, consequently, a very compact VCSEL cavity that exhibits microcavity effects very strongly."
"Another form of microcavity, the microdisk laser, is fabricated using the oxide process. The microdisk laser (10 $\mu$m in diameter) rests on the low-index, thermally conductive native oxide and exhibits laser modes characteristic of ""whispering gallery"" modes propagating around the perimeter of the disk. Low threshold pump intensities indicate that these microdisk lasers are high-Q cavities."
"By combining impurity-induced layer disordering (IILD) with the oxidation process, a planar minidisk laser is fabricated. The minidisk laser is larger in diameter (37 $\mu$m) and is entirely planar. The minidisk laser operates in ""whispering gallery"" modes around the perimeter of the disk, indicating the feasibility of the combination of processes in fabricating disk lasers."
"The same IILD + oxidation process is used to fabricate a two-dimensional active photonic lattice that is comprised of $\sim$9-$\mu$m microdisk lasers that are arranged in a triangular (hexagonal close-packed) lattice arrangement. The disks are closely spaced (11-$\mu$m center-to-center spacing) such that they are strongly coupled. As a result of the coupling of the disks, the photonic lattice exhibits laser operation in bands of energy located around the microdisk modes. In addition, the photonic lattice emits beams of energy along six symmetrical ""crystal"" directions. The details of photonic lattice fabrication and characterization are described."
Use this login method if you
don't
have an
@illinois.edu
email address.
(Oops, I do have one)
IDEALS migrated to a new platform on June 23, 2022. If you created
your account prior to this date, you will have to reset your password
using the forgot-password link below.