On the control of magnetospheric convection by the spatial distribution of ionospheric conductivities

A self-consistent semianalytical model of magnetospheric convection including the effect of the latitude and local time variations of ionospheric conductivities is presented. The motions of the inner edge of the magnetospheric ring current, and the associated field-aligned currents, produced by the externally imposed dawn-to-dusk potential drop across the magnetospheric cavity are computed by using a linear approximation. The coupling between the different diurnal harmonics in the local time variations of fields and currents produced by the local time dependence of ionospheric conductivities is described by an appropriate matrix formalism. The calculations show that the enhancement of auroral conductivities by electron precipitation in the auroral zone significantly enhances both the typical duration and the absolute amplitude of the penetration of convection electric fields to midlatitudes. Furthermore, the local time variations of the convection electric field generated at midlatitudes by a sudden increase of the dawn-to-dusk potential drop are in good agreement, both at the initial time and after the steady state is reached, with the available statistical models of the disturbance midlatitude electric field. The amplitude of the steady state field seems sufficient to explain these observations, thus confirming that the concept of the shielding of midlatitudes from the convection electric fields is basically correct but was overestimated in earlier analytical calculations. The large subauroral electric fields observed by several satellites are also reproduced in the model either by a decrease of the subauroral conductivities below the midlatitude values or by the consideration of a very narrow latitudinal extent of the auroral zone. The overall consistency between the results of the model and the electric field observations thus supports the idea that a large class of phenomena related to magnetospheric convection in the dipole regions of the magnetosphere can be described in a reasonably realistic manner by a linear theory.

[1]  M. Blanc Midlatitude convection electric fields and their relation to ring current development , 1978 .

[2]  R. Wolf,et al.  DYNAMICS OF THE MAGNETOSPHERIC PLASMA , 1979 .

[3]  E. Teller,et al.  Stability of the Adiabatic Motion of Charged Particles in the Earth's Field , 1960 .

[4]  V. Vasyliūnas,et al.  Mathematical models of magnetospheric convection and its coupling to the ionosphere , 1970 .

[5]  A. J. Zmuda,et al.  The diurnal flow pattern of field‐aligned currents , 1974 .

[6]  J. Testud,et al.  Middle and low latitude effects of auroral disturbances from incoherent-scatter , 1975 .

[7]  C. Reddy,et al.  Global scale electrodynamic coupling of the auroral and equatorial dynamo regions , 1979 .

[8]  D. T. Farley,et al.  Equatorial electric fields during magnetically disturbed conditions 1. The effect of the interplanetary magnetic field , 1979 .

[9]  R. Heelis,et al.  Ion convection velocity reversals in the dayside cleft , 1976 .

[10]  J. V. Evans,et al.  The penetration of convection electric fields to the latitude of Millstone Hill (Λ=56°) , 1981 .

[11]  Richard A. Wolf,et al.  Self‐consistent calculation of the motion of a sheet of ions in the magnetosphere , 1973 .

[12]  D. Stern Large-scale electric fields in the Earth's magnetosphere , 1977 .

[13]  W. J. Burke,et al.  Intense poleward‐directed electric fields near the ionospheric projection of the plasmapause , 1977 .

[14]  T. Potemra,et al.  The amplitude distribution of field-aligned currents at northern high latitudes observed by TRIAD. Interim report , 1975 .

[15]  R. Wolf,et al.  An assessment of the role of precipitation in magnetospheric convection , 1978 .

[16]  D. Stern,et al.  Adiabatic Hamiltonian of charged particle motion in a dipole field. [geomagnetic trapping] , 1975 .

[17]  D. Gurnett,et al.  Double-probe measurements of convection electric fields with the Injun-5 satellite , 1971 .

[18]  C. O. Hines,et al.  A UNIFYING THEORY OF HIGH-LATITUDE GEOPHYSICAL PHENOMENA AND GEOMAGNETIC STORMS , 1961 .

[19]  V. Vasyliūnas,et al.  The Interrelationship of Magnetospheric Processes , 1972 .

[20]  J. Evans Measurements of horizontal drifts in the E and F regions at Millstone Hill , 1972 .

[21]  G. Siscoe,et al.  Birkeland currents as the cause of the low‐latitude asymmetric disturbance field , 1981 .

[22]  A. Richmond Equatorial electrojet-I. Development of a model including winds and instabilities , 1973 .

[23]  T. Potemra,et al.  Large‐scale characteristics of field‐aligned currents associated with substorms , 1978 .

[24]  R. Wolf Calculations of Magnetospheric Electric Fields , 1974 .

[25]  R. W. Spiro,et al.  Quantitative simulation of a magnetospheric substorm 1. Model logic and overview , 1981 .

[26]  R. W. Spiro,et al.  Dependence of polar cap potential drop on interplanetary parameters , 1981 .

[27]  S. Matthews,et al.  The diurnal and latitudinal variation of auroral zone ionospheric conductivity , 1981 .

[28]  M. Blanc Magnetospheric convection effects at mid‐latitudes: 1. Saint‐Santin observations , 1983 .

[29]  R. Wand A model representation of the ionospheric electric field over Millstone Hill (Λ=56°) , 1981 .

[30]  R. Spiro,et al.  Quantitative simulation of a magnetospheric substorm. 3. plasmaspheric electric fields and evolution of the plasmapause. Scientific report , 1980 .

[31]  D. Stern The electric field and global electrodynamics of the magnetosphere: Review and Quadrennial Report to the IUGG , 1979 .

[32]  J. Heppner Polar‐cap electric field distributions related to the interplanetary magnetic field direction , 1972 .

[33]  M. Blanc Magnetospheric convection effects at mid‐latitudes: 3. Theoretical derivation of the disturbance convection pattern in the plasmasphere , 1983 .

[34]  Arthur D. Richmond,et al.  The ionospheric disturbance dynamo , 1980 .

[35]  Ronald F. Woodman,et al.  Vertical drift velocities and east‐west electric fields at the magnetic equator , 1970 .

[36]  P. Banks,et al.  Electric fields and conductivity in the nighttime E-region: A new magnetosphere-ionosphere-atmosphere coupling effect , 1978 .

[37]  R. Hoffman,et al.  Direct observations in the dusk hours of the characteristics of the storm-time ring current particles during the beginning of magnetic storms , 1974 .

[38]  C. Senior,et al.  Relationship between field‐aligned currents, diffuse auroral precipitation and the westward electrojet in the early morning sector , 1982 .

[39]  J. Heppner Empirical models of high latitude electric fields , 1977 .

[40]  R. W. Spiro,et al.  Computer simulation of inner magnetospheric dynamics for the magnetic storm of July 29, 1977 , 1982 .

[41]  G. Siscoe Polar cap size and potential: A predicted relationship , 1982 .

[42]  L. Frank Relationship of the plasma sheet, ring current, trapping boundary, and plasmapause near the magnetic equator and local midnight , 1971 .

[43]  B. Fejer,et al.  An explanation for anomalous equatorial ionospheric electric fields associated with a northward turning of the interplanetary magnetic field , 1979 .

[44]  F. Mozer,et al.  The average auroral zone electric field , 1974 .

[45]  R. Wolf Effects of ionospheric conductivity on convective flow of plasma in the magnetosphere , 1970 .