• DocumentCode
    3501627
  • Title

    Laboratory investigation of the propagation and ducting of whistler-waves

  • Author

    Amatucci, William E. ; Ganguli, G. ; Walker, D.N. ; Gatling, George

  • Author_Institution
    Div. of Plasma Phys., Naval Res. Lab., Washington, DC, USA
  • fYear
    2004
  • fDate
    1-1 July 2004
  • Firstpage
    164
  • Abstract
    Summary form only given. There have been a number of interesting in situ and laboratory observations of whistler wave propagation and stimulated emissions over the past few decades. For example, Stenzel [1975] reported on the self-ducting of large amplitude whistler waves in a laboratory plasma. Those experiments showed that with increasing amplitude, the radiation pattern from a small dipole antenna becomes increasingly narrow, and ultimately forms a duct with diameter of the order of the parallel wavelength. The ducted waves were observed to propagate virtually undamped along the length of the plasma column. In the space environment, observations of artificially stimulated VLF emissions triggered in the magnetosphere by whistler modes from VLF transmitters have been reported by Stiles and Helliwell [1975]. Emission radiation is assumed to come from the transverse currents formed by counter-streaming electrons that have been temporarily phase bunched by the constant frequency triggering signal. These observations have prompted a new NRL Space Physics Simulation Chamber investigation of whistler wave dynamics in a simulated radiation belt environment. The ultimate goals of these experiments are to understand and quantify ducting, self-focusing, and amplification of whistler waves, to investigate nonlinear whistler-plasma interactions, and to study the secondary emission of whistler waves. The initial experiments concentrates on the ducting of whistler waves in pre-existing density depletions and enhancements. Density structures with controllable scale size and depth is created using methods previously developed for a Space Chamber investigation of the dynamics of magnetospheric boundary layers.
  • Keywords
    antennas in plasma; magnetospheric electromagnetic wave propagation; plasma boundary layers; plasma density; plasma interactions; plasma nonlinear waves; plasma simulation; radiation belts; radiowave propagation; NRL Space Physics Simulation Chamber investigation; VLF transmitters; constant frequency triggering signal; counter streaming electrons; density depletions; dipole antenna radiation pattern; emission radiation; in situ observation; laboratory observations; laboratory plasma; magnetosphere; magnetospheric boundary layer dynamics; nonlinear whistler-plasma interactions; plasma column; secondary emission; simulated radiation belt environment; space environment; stimulated emissions; transverse currents; whistler wave ducting; whistler wave dynamics; whistler wave propagation; Antenna radiation patterns; Antennas and propagation; Dipole antennas; Ducts; Electron emission; Laboratories; Magnetosphere; Plasma waves; Stimulated emission; Transmitters;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Plasma Science, 2004. ICOPS 2004. IEEE Conference Record - Abstracts. The 31st IEEE International Conference on
  • Conference_Location
    Baltimore, MD, USA
  • ISSN
    0730-9244
  • Print_ISBN
    0-7803-8334-6
  • Type

    conf

  • DOI
    10.1109/PLASMA.2004.1339712
  • Filename
    1339712