High Performance Multi Barrier Thermionic Devices

Abstract

Thermoelectric transport perpendicular to layers in multiple barrier superlattice structures is investigated theoretically in two limiting cases of no lateral momentum scattering and strong scattering. In the latter regime when lateral momentum is not conserved, the number of electrons participating in thermionic emission will dramatically increase. The cooling power density is calculated using Fermi-Dirac statistics, density-of-states for a finite quantum well and the quantum mechanical transmission coefficient in the superlattice. Calculation results show that metallic based superlattices with tall barriers (>10 eV) can achieve a large power factor on the order of 0.06W/mK squared with a moderate electronic contribution to thermal conductivity of 1.8W/mK. If the lattice contribution to thermal conductivity is on the order of 1W/mK, ZT values higher than 5 can be achieved at room temperature.

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Document Details

Document Type
Technical Report
Publication Date
Jan 01, 2003
Accession Number
ADA461854

Entities

People

  • Ali H. Shakouri
  • Daryoosh Vashaee

Organizations

  • University of California, Santa Cruz

Tags

Communities of Interest

  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Coefficients
  • Conversion
  • Electrical Conductivity
  • Electron Gas
  • Emission
  • Energy Bands
  • Energy Conversion
  • Figure Of Merit
  • Free Electrons
  • Heterojunctions
  • Materials
  • Optoelectronic Devices
  • Quantum Wells
  • Semiconductors
  • Thermal Conductivity
  • Thermionic Emission
  • Three Dimensional

Fields of Study

  • Materials science
  • Physics

Readers

  • Plasma Physics / Magnetohydrodynamics
  • Quantum Dot Semiconductor Device Photonics and Graphene Optoelectronic Materials and THz Physics.
  • Solar Photovoltaics and Thermoelectric Devices.

Technology Areas

  • Microelectronics
  • Microelectronics - Graphene
  • Quantum Computing