• DocumentCode
    2073440
  • Title

    Terahertz electromagnetic wave amplification by lateral double-quantum-wire superlattice subject current-driven plasmon instability

  • Author

    Aizin, Gregory R. ; Mourokh, L.G. ; Kovalev, V.M. ; Horing, N. J M

  • Author_Institution
    Dept. of Phys. Sci., Kingsborough Coll., Brooklyn, NY, USA
  • Volume
    1
  • fYear
    2003
  • fDate
    12-14 Aug. 2003
  • Firstpage
    228
  • Abstract
    The electrodynamic interaction of an incident terahertz electromagnetic wave with a current-carrying lateral double-quantum-wire superlattice is analyzed here. The superlattice (in the x-y plane) is assumed to consist of two parallel quantum-wire sublattices, each of period a, shifted with respect to each other by distance d in the transverse y-direction. The parallel quantum wires of the sublattices are oriented in the x-direction. The two sublattices are taken to carry equal steady currents in opposite directions, and are coupled by Coulomb forces alone, with tunneling neglected. We recently showed that quasi-ID plasmons of such double-quantum-wire superlattice systems become unstable when the electron drift velocity falls between the phase velocities of the acoustic and optical plasma modes of the Coulomb-coupled wire subsystems. Here, a standard RPA formulation of plasmon dispersion taken jointly with the full system of Maxwell equations is employed to describe the electrodynamic interaction of incident terahertz electromagnetic radiation with the superlattice electron system at the plasmon resonant frequencies. Coupling of the electromagnetic wave with plasmon excitations is provided by introducing a metal grating with the grating stripes oriented perpendicular to the quantum wires. We have determined the transmission, absorption and reflection coefficients for an incident terahertz electromagnetic wave propagating through the grating-superlattice system, demonstrating that amplification of the terahertz electromagnetic radiation occurs in the region of plasma instability. Numerical estimates made for GaAs-based structures show that this effect occurs at experimentally achievable drift velocities.
  • Keywords
    III-V semiconductors; Maxwell equations; RPA calculations; absorption coefficients; gallium arsenide; numerical analysis; plasmons; semiconductor plasma; semiconductor quantum wires; semiconductor superlattices; submillimetre wave propagation; Coulomb coupled wire subsystems; Coulomb forces; GaAs; GaAs based structures; Maxwell equations; RPA; absorption coefficients; acoustic plasma modes; current carrying lateral double quantum wire superlattices; current driven plasmon instability; electrodynamic interaction; electron drift velocity; grating stripes; grating superlattice system; metal grating; optical plasma modes; plasma instability; plasmon dispersion; plasmon excitations; plasmon resonant frequencies; reflection coefficients; terahertz electromagnetic radiation; terahertz electromagnetic wave amplification; transmission coefficients; tunneling; Electrodynamics; Electromagnetic analysis; Electromagnetic radiation; Electromagnetic scattering; Electron mobility; Gratings; Plasma waves; Plasmons; Superlattices; Wires;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Nanotechnology, 2003. IEEE-NANO 2003. 2003 Third IEEE Conference on
  • Print_ISBN
    0-7803-7976-4
  • Type

    conf

  • DOI
    10.1109/NANO.2003.1231757
  • Filename
    1231757