Transport Modeling of Multiple-Quantum-Well Optically Addressed Spatial Light Modulators

Abstract

Optically addressed spatial light modulators are essential elements in any optical processing system. Applications such as optical image correlation, short pulse auto-correlation, and gated holography require high speed, high resolution devices for use in compact, high throughput systems. Other important device criteria include ease of fabrication and operation. In this work we study the transport dynamics of a new kind of optically addressed spatial light modulator that uses semi-insulating or intrinsic quantum-well material to produce high performance devices without the need for pixellation or complicated device design. In response to an incident intensity pattern, basic device operation occurs through the screening of an applied voltage via the optical generation, transport, and trapping of photocarriers. A field pattern which mimics the incident intensity pattern is produced by the screening process. This generates strong index and absorption holograms via the quantum confined Stark effect. These holograms can be read out simultaneously with a probe beam to provide dynamic read/write operation. Overall device performance is determined by the transport of photocarriers during the field screening process. We have developed a transient, two-dimensional drift-diffusion model to describe both free and well-confined carrier transport as well as nonlinear effects such as velocity saturation and field-dependent carrier emission from quantum wells. Various analytical and numerical results for the internal carrier and space charge distributions, different screening regimes, and relative carrier contributions to the screening process are given. An experimental characterization of a GaAs/AlGaAs device using optical transmission and photocurrent techniques is also presented and used to verify the main results of the transport model. Analytical and numerical analyses of various transport effects that limit the resolution are also given.

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Document Details

Document Type
Technical Report
Publication Date
Dec 01, 1996
Accession Number
ADA355321

Entities

People

  • Stephen L. Smith

Organizations

  • Stanford University

Tags

Communities of Interest

  • Advanced Electronics
  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Boltzmann Equation
  • Compound Semiconductors
  • Diffraction
  • Electron Density
  • Electronics Laboratories
  • Laser Diodes
  • Modulation
  • Optical Correlators
  • Optical Modulators
  • Optical Properties
  • Optics
  • Pockels Effect
  • Power Electronics
  • Quantum Wells
  • Refractive Index
  • Scattering
  • Semiconductors

Fields of Study

  • Materials science
  • Physics

Readers

  • Computational Modeling and Simulation
  • Optical Physics and Photonics.
  • Quantum Dot Semiconductor Device Photonics and Graphene Optoelectronic Materials and THz Physics.

Technology Areas

  • Microelectronics
  • Quantum Computing
  • Space
  • Space - Hall-Effect Thruster