• DocumentCode
    1926132
  • Title

    PLASMON: Data assimilation of the Earth´s plasmasphere

  • Author

    Collier, Andrew B. ; Lichtenberger, János ; Clilverd, Mark ; Heilig, Balázs ; Vellante, Massimo ; Manninen, Jyrki ; Rodger, Craig ; Jorgensen, Anders ; Reda, Jan ; Holzworth, Robert ; Friedel, Reiner

  • Author_Institution
    Hermanus Magn. Obs., Hermanus, South Africa
  • fYear
    2011
  • fDate
    13-20 Aug. 2011
  • Firstpage
    1
  • Lastpage
    1
  • Abstract
    The principal source and loss mechanisms in the Earth´s radiation belts are currently not completely understood. Loss rates are important since they determine the duration of exposure of satellites to enhanced radiation conditions during a geomagnetic storm. The dominant loss process is relativistic electron precipitation via resonant interactions with a variety of wave modes. These interactions are governed by the characteristics of the plasmasphere. Current models provide an inadequate representation of the spatial and temporal evolution of the plasmasphere. In situ measurements of the plasmasphere provide only local characteristics and are thus unable to yield a complete global picture. Ground based measurements, based on the analysis of Very Low Frequency (VLF) whistlers and Field Line Resonances (FLRs), are able to describe large sections of the plasmasphere, extending over significant radial distances and many hours of local time. These measurements provide electron number and plasma mass densities. PLASMON is a funded FP7 project between 11 international partners. PLASMON intends to assimilate near real time measurements of plasmaspheric densities into a dynamic plasmasphere model. The VLF whistler analyses will be conducted by automatic retrieval of equatorial electron densities using data from AWDAnet. Equatorial mass densities will be constructed from FLR measurements along meridional magnetometer chains. The resulting model will facilitate the prediction of precipitation rates. The predicted rates will be compared to observations from the AARDDVARK network.
  • Keywords
    atmospheric electron precipitation; atmospheric techniques; magnetic storms; magnetospheric electromagnetic wave propagation; plasma density; plasmons; radiation belts; whistlers; AARDDVARK network; AWDAnet data; Earth plasmasphere; Earth radiation belts; FP7 project; VLF whistlers; data assimilation; dominant loss process; dynamic plasmasphere model; electron number; equatorial electron densities; field line resonances; geomagnetic storm; loss mechanism; loss rates; meridional magnetometer chains; plasma mass densities; plasmasphere characteristics; plasmasphere evolution; plasmaspheric density measurements; precipitation rates; principal source mechanism; radiation conditions; relativistic electron precipitation; very low frequency; wave modes; Density measurement; Geophysical measurements; Magnetic field measurement; Magnetic resonance; Plasma measurements; Plasmons; USA Councils;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    General Assembly and Scientific Symposium, 2011 XXXth URSI
  • Conference_Location
    Istanbul
  • Print_ISBN
    978-1-4244-5117-3
  • Type

    conf

  • DOI
    10.1109/URSIGASS.2011.6051134
  • Filename
    6051134