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Effects of energetic electrons on the electrodynamics in the ionosphere

By A. Aksnes, J. Stadsnes, G. Lu, N. Østgaard, R.R. Vondrak, D.L. Detrick, T.J. Rosenberg and G.A. Germany
Year: 2004
DOI identifier: 10.5194/angeo-22-475-2004
OAI identifier: oai:eprints.lancs.ac.uk:35411
Provided by: Lancaster E-Prints

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  1. (1985). A high-latitude phenomenological model of auroral precipitation and ionospheric effects, doi
  2. A relation between the energy deposition by electron precipitation and geomagnetic indices during substorms, doi
  3. (1985). A statistical model of auroral electron precipitation, doi
  4. (1989). A statistical model of auroral ion precipitation, doi
  5. (1991). A statistical model of auroral ion precipitation, 2, Functional representation of the average patterns, doi
  6. (1991). A storm time assimilative mapping of ionospheric electrodynamics analysis for the severe geomagnetic storm of doi
  7. A study of the dynamics of a discrete auroral arc, doi
  8. (1996). A substorm observed by EISCAT and other ground-based instruments – evidence for near-Earth substorm initiation, doi
  9. (1969). A synoptic investigation of particle precipitation dynamics for 60 substorms in IQSY (1964–65) and IASY doi
  10. (1992). A thermosphere/ionosphere general circulation model with coupled electrodynamics, doi
  11. A. Aksnes et al.: Effects of energetic electrons on ionospheric electrodynamics
  12. (1988). A.: Auroral studies with a chain of meridian scanning photometers, 2, Mean distributions of proton and electron aurora as a function of magnetic activity, doi
  13. (1997). AFSPCPAM15-2: Space Environmental Impacts on DOD Operations, Air Force Space Command Pamphlet 15-2, 53 pp., Air Force Space Command, Peterson AFB,
  14. (1999). Aksnes et al.: Effects of energetic electrons on ionospheric electrodynamics
  15. (1998). Aksnes et al.: Effects of energetic electrons on ionospheric electrodynamics 495
  16. (1992). Assimilative mapping of ionospheric electrodynamics, doi
  17. (2001). Auroral electron distributions derived from combined UV and X-ray emissions, doi
  18. (1963). Auroral ionization and excitation by incident energetic electrons, doi
  19. (1988). Auroral zone E-region conductivities during solar minimum derived from EISCAT data,
  20. (1971). Auroral-zone X-ray events and their relation to polar magnetic substorms, doi
  21. (1975). Average characteristisc of magnetospheric electrons (150 eV to 200 keV) at 1400 km, doi
  22. (2000). Cause of the localized maximum of X-ray emission in the morning sector: A comparison with electron measurements, doi
  23. (1992). CEPXS/ONELD Version 2.0: A discrete ordinates code package for general one-dimensional coupled electronphoton transport, doi
  24. (1967). Changes in Van Allen radiation associated with polar substorms, doi
  25. (1975). E.: Average characteristisc of magnetospheric electrons (150eV to 200keV) at 1400km,
  26. Electric conductivities, electric fields and auroral particle energy injection rate in the auroral ionosphere and their empirical relations to the horizontal magnetic disturbances, doi
  27. (1969). Electric Fields in the Vicinity of Auroral Forms from Motions of Barium Vapor Releases, doi
  28. (1977). Electrodynamics of an Arc, doi
  29. (1973). Electrodynamics of the Ionosphere, in: Cosmical Geophysics, edited by
  30. (1979). Electron precipitation of evening diffuse aurora and its conjugate electron fluxes near the magnetospheric equator, doi
  31. (1981). Empirical models of height integrated conductivities, doi
  32. (1984). Energetics of the magnetosphere, doi
  33. Energy analysis of substorms based on remote sensing techniques, solar wind measurements and geomagnetic indices, doi
  34. (1998). Energy characterization of a dynamic auroral event using GGS UVI images, in: doi
  35. (1998). Energy characterization of a dynamic auroral event using GGS UVI images, in: Geospace Mass and Energy Flow: Results from the International Solar-Terrestrial Physics Program, edited by doi
  36. (1981). Energy coupling between the solar wind and the magnetosphere, doi
  37. Energy depostion by energetic particles and Joule dissipation in the auroral ionosphere, doi
  38. (1981). Estimation of ionospheric electric fields, ionospheric currents, and fieldaligned currents from ground magnetic records, doi
  39. (1992). et al.: High-latitude ionospheric electrodynamics as determined by the assimilative mapping of ionospheric electrodynamics procedure for the conjunctive SUNDIAL/ATLAS 1/GEM period of doi
  40. (1992). etal.: High-latitudeionospheric electrodynamics as determined by the assimilative mapping of ionospheric electrodynamics procedure for the conjunctive SUNDIAL/ATLAS 1/GEM period of doi
  41. (1993). G et al.: An overview of the early doi
  42. Global distribution of ionospheric and field-aligned currents during substorms as determined from six IMS meridian chains of magnetometers: Initial results, doi
  43. (1997). Global energy deposition during the doi
  44. (1990). Global measures of ionospheric electrodynamic activity inferred from combined incoherent scatter radar and ground magnetometer observations, doi
  45. (1993). Ground-based measurements of an arc-associated electric field, doi
  46. (2000). Height-integrated conductivity in auroral substorms. doi
  47. (1987). Height-integrated Pedersen and Hall conductivity patterns inferred from the TIROS-NOAA satellite data, doi
  48. (1984). Hemispherical Joule heating and the AE indices, doi
  49. (1991). Identification and observations of the plasma mantle at low altitude, doi
  50. (2001). Impact of model differences on quantitative analysis of FUV auroral emissions: Total ionization cross sections, doi
  51. (1985). Inference of high-latitude ionization and conductivity from AE-C measurements of auroral electron fluxes, doi
  52. (2002). Instantaneous ionospheric global conductance maps during an isolated substorm, doi
  53. (1999). Ionization by energetic protons in Thermosphere-Ionosphere Electrodynamics General Circulation Model, doi
  54. (1988). Ionospheric conductivities, electric fields and currents associated with auroral substorms measured by the EISCAT radar, doi
  55. (1986). Ionospheric convection associated with discrete levels of particle precipitation, doi
  56. (1995). Ionospheric electrodynamics using magnetic apex coordinates, doi
  57. L.J.: Precipitatingelectron energy flux and auroral zone conductances – an empirical model, doi
  58. (1972). Magnetic apex coordinates: A magnetic coordinate system for the ionospheric F2-layer, doi
  59. (1988). Mapping electrodynamic features of the high-latitude ionosphere from localized observations: doi
  60. (1988). Mapping electrodynamic featuresofthehigh-latitudeionospherefromlocalizedobservations:
  61. Mapping of auroral X rays from rocket overflights, doi
  62. (1967). N.M.: Thegeneralpatternofauroralparticle precipitation,
  63. (1987). On calculating ionospheric conductances from the flux and energy of precipitating electrons, doi
  64. On the interaction of auroral protons with the Earth’s atmosphere, doi
  65. (1975). On the morphology of auroralzone X-ray events-IV. Substorm-related electron precipitation in the local morning sector, doi
  66. (1995). P.: A far ultaviolet imager for the international solarterrestrial physics mission, doi
  67. Precipitating electron energy flux and auroral zone conductances – an empirical model, doi
  68. (1998). Progress on relating optical auroral forms and electric field patterns, doi
  69. (1981). Quantitative simulation of a magnetospheric substorm, doi
  70. (1976). Radar measurements of the latitudinal variation of auroral ionization, doi
  71. (1995). Radar observations of auroral zone flows during a multiple-onset substorm, doi
  72. (1977). Radar Observations of Electric Fields and Currents Associated With Auroral Arcs, doi
  73. (1990). Regions of strongly enhanced perpendicular electric fields adjacent to auroral arcs, doi
  74. (1998). Relationship between large horizontal electric fields and auroral arc elements, doi
  75. (1997). Remote determination of auroral energy characteristics during substorm activity, doi
  76. (2001). Response of the upper atmosphere to auroral protons, doi
  77. (1970). Rocket Measurements of Auroral Electric and Magnetic Fields, doi
  78. (1987). Statistical and functional representations of the pattern of auroral energy flux, number flux, and conductivity, doi
  79. (1966). The collision frequency in the E- doi
  80. (1990). The dependence of modeled OI 1356 and N2 LBH auroral emissions on the neutral atmosphere, doi
  81. (1986). The effective recombination coefficient of electrons doi
  82. (1986). The effective recombination coefficient of electrons in the ionosphere between 50 and 150 km, doi
  83. (1995). The efficiency of “viscous interaction” between the solar wind and the magnetosphere during intense northward IMF events, doi
  84. (1956). The electrical conductivity of the ionosphere: A review, doi
  85. (2001). The electron and proton aurora as seen by IMAGE-FUV and FAST, doi
  86. (1967). The general pattern of auroral particle precipitation, doi
  87. The Joule heat production rate and the particle energy injection rate as a function of the geomagnetic indices AE doi
  88. (1995). The Polar Ionospheric X-ray Imaging Experiment (PIXIE), doi
  89. (1994). The relationship between ionospheric convection and magnetic activity, doi
  90. (1994). What is a geomagnetic storm?, doi

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