Geoscience Reference
In-Depth Information
Sorokin VM, Chmyrev VM (1999) Modification of the ionosphere by seismic related electric field.
In: Hayakawa M (ed) Atmospheric and ionospheric electromagnetic phenomena associated
with earthquakes. Terra Scientific Publishing Company (TERRAPUB), Tokyo, pp 805-818
Sorokin VM, Chmyrev VM, Yaschenko AK (2005a) Theoretical model of DC electric field
formation in the ionosphere stimulated by seismic activity. J Atmos Solar-Terr Phys 67:
1259-1268
Sorokin VM, Yaschenko AK, Chmyrev VM, Hayakawa M (2005b) DC electric field amplification
in the mid-latitude ionosphere over seismically active faults. Nat Hazards Earth Syst Sci 5:
661-666
Sorokin VM, Yaschenko AK, Hayakawa M (2006) Formation mechanism of the lower-ionosphere
disturbances by the atmosphere electric current over a seismic region. J Atmos Solr-Terr Phys
68:1260-1268
Sorokin VM, Yaschenko AK, Hayakawa M (2007) A perturbation of DC electric field caused by
light ion adhesion to aerosols during the growth in seismic-related atmospheric radioactivity.
Nat Hazards Earth Syst Sci 7:155-163
Sutton EK, Forbes JM, Nerem RS (2005) Global thermospheric neutral density and wind response
to the severe 2003 geomagnetic storms from CHAMP accelerometer data. J Geophys Res
110:A09S40. doi:
10.1029/2004JA010985
Sutton EK, Nerem RS, Forbes JM (2007) Density and winds in the thermosphere deduced from
accelerometer data. J Spacecraft Rockets 44(N. 6):1210-1219
Thayer JP, Killeen TL (1993) A kinematic analysis of the high-latitude thermospheric neutral
circulation pattern. J Geophys Res 98(N. A7):11549-11565
Thuillier G, Perrin J-M, Lathuillere C, Herse M, Fuller-Rowell T, Codrescu M, Huppert F,
Fehrenbach M (2005) Dynamics in the polar thermosphere after the coronal mass ejection of 28
October 2003 observed with the EPIS interferometer at Svalbard. J Geophys Res 110:A09S37.
doi:
10.1029/2004JA010966
Toth G, De Zeeuw DL, Gombosi TI, Manchester WB, Ridley AJ, Sokolov IV, Roussev II (2007)
Sun-to-thermosphere simulation of the 28-30 October 2003 storm with the space weather
modeling framework. Space Weather 5:S06003. doi:
10.1029/2006SW000272
Tsurutani BT et al (2005) The October 28, 2003 extreme EUV solar flare and resultant extreme
ionospheric effects: comparison to other Halloween events and the Bastille Day event. Geophys
Res Lett 32:L03S09. doi
:
10.1029/2004GL021475
Va s y l i ¯unas VM (2007) The mechanical advantage of the magnetosphere: solar-wind-related forces
in the magnetosphere-ionosphere-earth system. Ann Geophys 25:255-269. doi:
10.5194/an-
geo-25-255-2007
Villante U, Regi M (2008) Solar flare effect preceding Halloween storm (28 October 2003): results
of a worldwide analysis. J Geophys Res 113:A00A05. doi:
10.1029/2008JA013132
Volkov MA, Namgaladze AA (1996) Model calculations of the field-aligned currents and electric
fields during the substorm expansion phase. Geomagn Aeron 36:438-444 (in Russian)
Weimer DR (1995) Models of high-latitude electric potentials derived with a least error fit of
spherical harmonic coefficients. J Geophys Res 100(N. A10):19595-19607
Weimer DR (2005) Improved ionospheric electrodynamic models and application to calculating
Joule heating rates. J Geophys Res 110(N. A5):A05306. doi:
10.1029/2004JA010884
Weimer DR, Ober DM, Maynard NC, Collier MR, McComas DJ, Ness NF, Smith CW,
Watermann J (2003) Predicting interplanetary magnetic field (IMF) propagation delay times
using the minimum variance technique. J Geophys Res 108:1026. doi:
10.1029/2002JA009405
Wessel P, Smith WHF (1998) New, improved version of generic mapping tools released. EOS
Trans 79:579-1998
Zakharenkova IE, Shagimuratov II, Krankowski A, Lagovsky AF (2007a) Precursory phenomena
observed in the total electron content measurements before great Hokkaido earthquake of
September 25, 2003 (M
8.3). Stud Geophys Geod 51(N. 2):267-278
Zakharenkova IE, Shagimuratov II, Krankowski A (2007b) Features of the ionosphere behavior
before Kythira 2006 earthquake. Acta Geophysica 55(N. 4):524-534
D
