High-speed oxide-VCSELS for optical data links in data center and cryogenic computing applications
Fu, Wenning
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https://hdl.handle.net/2142/120327
Description
Title
High-speed oxide-VCSELS for optical data links in data center and cryogenic computing applications
Author(s)
Fu, Wenning
Issue Date
2023-01-04
Director of Research (if dissertation) or Advisor (if thesis)
Feng, Milton
Doctoral Committee Chair(s)
Feng, Milton
Committee Member(s)
Jin, Jianming
Dragic, Peter D
Lee, Minjoo Lawrence
Department of Study
Electrical & Computer Eng
Discipline
Electrical & Computer Engr
Degree Granting Institution
University of Illinois at Urbana-Champaign
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
High-Speed Communication
Oxide VCSELs
Abstract
In recent years, there is a growing demand for a high-speed and power-efficient data extraction from cryogenic environments, such as superconducting processors based on single flux quantum (SFQ) technology at 4 Kelvin (K). To achieve such data transfer from 4 K to room-temperature electronics, optical data links based on cryogenic VCSELs at 4 K or an intermediate temperature are promising solutions due to low signal loss and low heat leak in fibers.
The main work demonstrated in this dissertation is the development of a record high-speed cryogenic VCSEL with optical data transmission over 50 Gb/s from liquid-nitrogen and liquid-helium temperature to room-temperature electronics. Furthermore, the bandwidth measurement, microwave modeling, and parameter extraction have indicated that the capability of the cryogenic VCSELs is far beyond 50 Gb/s data rate. The extracted intrinsic bandwidth of 88.7 GHz at liquid-nitrogen temperature projects to a 200 Gb/s, sub-100 fJ/bit single-VCSEL, single-fiber data link. Also reported is the first demonstration that superconducting circuits are used to modulate a fully packaged VCSEL for up to 20 Gb/s NRZ data transmission via a fiber link from 4 K all the way to room-temperature users. The data rate is limited by the superconducting processor available to use. The authors believe that this work paves the way for next-generation cryogenic computing technologies by solving one of the key issues: the need of a high-speed, efficient, and low-heat-leak data communication between cryogenic and room-temperature environments.
To make a transition into the cryogenic VCSEL development chapter, room-temperature VCSEL development, which was partially contributed by the author, is presented first. For many years, room-temperature GaAs-based 850nm VCSELs have been deployed in data centers for short-reach optical data links. However, there is a constant need to increase the link speed to accommodate the ever-growing data traffic. The dissertation will discuss operation physics, emerging challenges, and solutions in the development of VCSELs for 50 Gb/s NRZ data link over 100 meters OM4 fiber and operation up to 115 °C.
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