Monolithic Integration of Solid State Thermionic Coolers with Semiconductor Lasers

Abstract

We examine the cooling requirements and temperature stabilization needs of semiconductor lasers. Monolithic integration of thin film solid state thermionic coolers for laser applications is proposed and experimental results on an integrated structure are discussed. Many types of semiconductor lasers such as vertical cavity surface emitting lasers (VCSEL s) or distributed feedback (DFB) lasers can generate large heat power densities on the order of kW/cm2 over areas as small as 100mm2 [1]. Under these conditions, the active region can reach temperatures greater than 70 C above the heat sink temperature. It is desirable in many applications to control the operating temperature in order to tune the operating characteristics such as emission wavelength or to enhance the performance such as increasing the output power. Conventionally, thermoelectric (TE) coolers are used to manage temperature, however since they are not easily integrated with semiconductor devices [2], the packaging can be costly. Moreover, the TE device usually determines the reliability and lifetime of a packaged laser module [3]. An alternative to traditional TE coolers is heterostructure integrated thermionic coolers. These thin film coolers use the selective emission of hot electrons over a heterostructure barrier layer from emitter to collector resulting in an evaporative cooling of the electron gas beyond what is possible with the Peltier effect [4]. Thermionic coolers fabricated in the InGaAsP material system have demonstrated cooling on the order of several degrees over one-to two micron thick barriers (see fig.1) and cooling power densities of over 100 W/cm2 [5,6]. This cooling power density is approximately an order of magnitude greater than what is possible with TE coolers. The InGaAsP material system is important for long wavelength semiconductor lasers used in long haul and other high-speed optical communication systems.

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Document Details

Document Type
Technical Report
Publication Date
Jan 01, 2000
Accession Number
ADA461130

Entities

People

  • Ali Shakouri
  • Christopher Labounty
  • David Oberl
  • Joachim Piprek
  • John E. Bowers
  • Patrick Abraham

Organizations

  • University of California, Santa Barbara

Tags

Communities of Interest

  • Advanced Electronics

DTIC Thesaurus Topics

  • Abstracts
  • Chemical Vapor Deposition
  • Communication Systems
  • Electronic Mail
  • Electrons
  • Emission
  • Engineering
  • Films
  • Heat Sinks
  • Laser Applications
  • Lasers
  • Materials
  • Military Research
  • Semiconductor Devices
  • Semiconductor Lasers
  • Semiconductors
  • Thin Films

Fields of Study

  • Materials science

Readers

  • Integrated Circuit Design and Technology.
  • Optical Physics and Photonics.
  • Solar Photovoltaics and Thermoelectric Devices.

Technology Areas

  • Directed Energy
  • Microelectronics