Determining the spectra of radiation belt electron losses : Fitting DEMETER IDP observations for typical and storm-times

The energy spectra of energetic electron precipitation from the radiation belts are studied in order to improve our understanding of the influence of radiation belt processes. The DEMETER microsatellite electron flux instrument is comparatively unusual in that it has very high energy resolution (128 channels with 17.9 keV widths in normal survey mode), which lends itself to this type of spectral analysis. Here electron spectra from DEMETER have been analyzed from all six years of its operation, and three fit types (power law, exponential and kappa-type) have been applied to the precipitating flux observations. We show that the power-law fit consistently provides the best representation of the flux, and that the kappa-type is rarely valid. We also provide estimated uncertainties in the flux for this instrument as a function of energy. Average power-law gradients for non-trapped particles have been determined for geomagnetically non-disturbed periods to get a typical global behavior of the spectra in the inner radiation belt, slot region, and outer radiation belt. Power law spectral gradients in the outer belt are typically -2.5 during quiet periods, changing to a softer spectrum of ∼-3.5 during geomagnetic storms. The inner belt does the opposite, hardening from -4 during quiet times to ∼-3 during storms. Typical outer belt e-folding values are ∼200 keV, dropping to ∼150 keV during geomagnetic storms, while the inner belt e-folding values change from ∼120 keV to >200 keV. Analysis of geomagnetic storm periods show that the precipitating flux enhancements evident from such storms take approximately 13 days to return to normal values for the outer belt and slot region, and approximately 10 days for the inner belt. D R A F T October 21, 2013, 7:45pm D R A F T WHITTAKER ET AL.: IDP FITTING COMPARISONS X 3

[1]  V. Angelopoulos,et al.  Evolution and slow decay of an unusual narrow ring of relativistic electrons near L ~ 3.2 following the September 2012 magnetic storm , 2013 .

[2]  Craig J. Rodger,et al.  Geomagnetic activity signatures in wintertime stratosphere wind, temperature, and wave response , 2013 .

[3]  R. Schlickeiser,et al.  Spontaneous electromagnetic fluctuations in unmagnetized plasmas. III. Generalized Kappa distributions , 2012 .

[4]  J. Sauvaud,et al.  Inner radiation belt particle acceleration and energy structuring by drift resonance with ULF waves during geomagnetic storms , 2012 .

[5]  C. Rodger,et al.  Precipitating radiation belt electrons and enhancements of mesospheric hydroxyl during 2004-2009 , 2012 .

[6]  M. Parrot,et al.  Study of the North West Cape electron belts observed by DEMETER satellite , 2012 .

[7]  J. Bortnik,et al.  Relativistic microburst storm characteristics: Combined satellite and ground-based observations , 2011, 2011 XXXth URSI General Assembly and Scientific Symposium.

[8]  P. Hartogh,et al.  Direct observations of nitric oxide produced by energetic electron precipitation into the Antarctic middle atmosphere , 2011 .

[9]  R. J. Gamble,et al.  Contrasting the efficiency of radiation belt losses caused by ducted and nonducted whistler-mode waves from ground-based transmitters , 2010 .

[10]  R. J. Gamble,et al.  Ground‐based estimates of outer radiation belt energetic electron precipitation fluxes into the atmosphere , 2010 .

[11]  A. Chulliat,et al.  International Geomagnetic Reference Field: the eleventh generation , 2010 .

[12]  R. J. Gamble,et al.  Radiation belt electron precipitation due to geomagnetic storms: Significance to middle atmosphere ozone chemistry , 2010 .

[13]  J. Green,et al.  Use of POES SEM-2 observations to examine radiation belt dynamics and energetic electron precipitation into the atmosphere , 2010 .

[14]  J. Borovsky,et al.  Electron loss rates from the outer radiation belt caused by the filling of the outer plasmasphere: the calm before the storm , 2009 .

[15]  C. Randall,et al.  Geomagnetic activity and polar surface air temperature variability , 2009 .

[16]  G. Brasseur,et al.  Aeronomy of the Middle Atmosphere , 2009 .

[17]  J. Tamminen,et al.  Impact of different energies of precipitating particles on NOx generation in the middle and upper atmosphere during geomagnetic storms , 2009 .

[18]  R. J. Gamble,et al.  Radiation belt electron precipitation due to VLF transmitters: Satellite observations , 2008 .

[19]  F. Xiao,et al.  Energetic electron distributions fitted with a relativistic kappa‐type function at geosynchronous orbit , 2008 .

[20]  R. Thorne,et al.  Review of radiation belt relativistic electron losses , 2007 .

[21]  M. Gangloff,et al.  High-energy electron detection onboard DEMETER: The IDP spectrometer, description and first results on the inner belt , 2006 .

[22]  Richard M. Thorne,et al.  Acceleration mechanism responsible for the formation of the new radiation belt during the 2003 Halloween solar storm , 2006 .

[23]  F. Xiao,et al.  Modelling energetic particles by a relativistic kappa-loss-cone distribution function in plasmas , 2006 .

[24]  D. Baker,et al.  An extreme distortion of the Van Allen belt arising from the ‘Hallowe'en’ solar storm in 2003 , 2004, Nature.

[25]  D. Baker,et al.  Testing loss mechanisms capable of rapidly depleting relativistic electron flux in the Earth's outer radiation belt , 2004 .

[26]  G. Reeves,et al.  Acceleration and loss of relativistic electrons during geomagnetic storms , 2003 .

[27]  R. Thorne,et al.  Instability of electromagnetic R-mode waves in a relativistic plasma , 1998 .

[28]  B. Tsurutani,et al.  Some basic concepts of wave‐particle interactions in collisionless plasmas , 1997 .

[29]  P. Riley,et al.  Ulysses electron distributions fitted with Kappa functions , 1997 .

[30]  V. Formisano,et al.  Solar wind interaction with the Earth's magnetic field: 1. Magnetosheath , 1973 .

[31]  J. Arens,et al.  Observations of trapped electrons at low and high altitudes , 1968 .

[32]  V. Vasyliūnas,et al.  A survey of low-energy electrons in the evening sector of the magnetosphere with OGO 1 and OGO 3. , 1968 .

[33]  R. J. Gamble The 17–19 January 2005 Atmospheric Electron Precipitation Event , 2011 .