Interhemispheric asymmetry of the high-latitude ionospheric convection pattern

The assimilative mapping of ionospheric electrodynamics technique has been used to derive the large-scale high-latitude ionospheric convection patterns simultaneously in both northern and southern hemispheres during the period of January 27-29, 1992. When the interplanetary magnetic field (IMF) Bz component is negative, the convection patterns in the southern hemisphere are basically the mirror images of those in the northern hemisphere. The total cross-polar-cap potential drops in the two hemispheres are similar. When Bz is positive and |By| > Bz, the convection configurations are mainly determined by By and they may appear as normal “two-cell” patterns in both hemispheres much as one would expect under southward IMF conditions. However, there is a significant difference in the cross-polar-cap potential drop between the two hemispheres, with the potential drop in the southern (summer) hemisphere over 50% larger than that in the northern (winter) hemisphere. As the ratio of |By|/Bz decreases (less than one), the convection configuration in the two hemispheres may be significantly different, with reverse convection in the southern hemisphere and weak but disturbed convection in the northern hemisphere. By comparing the convection patterns with the corresponding spectrograms of precipitating particles, we interpret the convection patterns in terms of the concept of merging cells, lobe cells, and viscous cells. Estimates of the “merging cell” potential drops, that is, the potential ascribed to the opening of the dayside field lines, are usually comparable between the two hemispheres, as they should be. The “lobe cell” provides a potential between 8.5 and 26 k V and can differ greatly between hemispheres, as predicted. Lobe cells can be significant even for southward IMF, if |By| > |Bz|. To estimate the potential drop of the “viscous cells,” we assume that the low-latitude boundary layer is on closed field lines. We find that this potential drop varies from case to case, with a typical value of 10 kV. If the source of these cells is truly a viscous interaction at the flank of the magnetopause, the process is likely spatially and temporally varying rather than steady state.

[1]  R. Heelis,et al.  Ionospheric convection signatures and magnetic field topology , 1987 .

[2]  R. Heelis,et al.  Dayside auroral arcs and convection , 1978 .

[3]  Mike Lockwood,et al.  Dependence of convective flows and particle precipitation in the high‐latitude dayside ionosphere on the X and Y components of the interplanetary magnetic field , 1991 .

[4]  L. Lyons Generation of large-scale regions of auroral currents, electric potentials, and precipitation by the divergence of the convection electric field , 1980 .

[5]  C. Clauer,et al.  Relationship of the interplanetary electric field to the high-latitude ionospheric electric field and currents: observations and model simulation , 1986 .

[6]  F. Mozer Electric field evidence on the viscous interaction at the magnetopause , 1984 .

[7]  R. P. Lepping,et al.  Mapping electrodynamic features of the high-latitude ionosphere from localized observations: Combined incoherent-scatter radar and magnetometer measurements for January 18-19, 1984 , 1988 .

[8]  R. G. Musgrove,et al.  Ionospheric convection associated with discrete levels of particle precipitation , 1986 .

[9]  Y. Feldstein,et al.  The auroral luminosity structure in the high-latitude upper atmosphere: Its dynamics and relationship to the large-scale structure of the Earth's magnetosphere , 1985 .

[10]  L. Lyons A simple model for polar cap convection patterns and generation of θ auroras , 1985 .

[11]  Wolfgang Baumjohann,et al.  Ionospheric and Birkeland current distributions for northward interplanetary magnetic field: Inferred polar convection , 1984 .

[12]  R. Heelis,et al.  Polar cap deflation during magnetospheric substorms , 1989 .

[13]  M. Saunders Magnetosheath, magnetopause and low latitude boundary layer research, 1987–1989 , 1990 .

[14]  E. W. Hones,et al.  Characteristics of the magnetospheric boundary layer and magnetopause layer as observed by Imp 6 , 1979 .

[15]  D. Croley,et al.  Low Energy Polar Cap Electrons during Quiet Times , 1975 .

[16]  H. W. Kroehl,et al.  Ionospheric convection response to changing IMF direction , 1991 .

[17]  W. J. Burke,et al.  Identification and observations of the plasma mantle at low altitude , 1991 .

[18]  P. Mizera,et al.  Satellite observations of polar, magnetotail lobe, and interplanetary electrons at low energies. Interim report , 1978 .

[19]  N. Crooker,et al.  Lobe cell convection as a summer phenomenon , 1993 .

[20]  Mike Lockwood,et al.  The excitation of plasma convection in the high‐latitude ionosphere , 1990 .

[21]  R. Heelis,et al.  Ionospheric convection signatures observed by De 2 during northward interplanetary magnetic field , 1986 .

[22]  G. Horneck,et al.  Heavy ion induced double strand breaks in bacteria and bacteriophages. , 1992, Advances in space research : the official journal of the Committee on Space Research.

[23]  W. J. Burke,et al.  Polar cap electric field structures with a northward interplanetary magnetic field , 1979 .

[24]  T. Eastman,et al.  Energetic Particle Observations in the Low‐Latitude Boundary Layer , 1985 .

[25]  J. Winningham,et al.  The latitudinal morphology of 10‐eV to 10‐keV electron fluxes during magnetically quiet and disturbed times in the 2100–0300 MLT sector , 1975 .

[26]  N. Maynard,et al.  Empirical high‐latitude electric field models , 1987 .

[27]  W. J. Burke,et al.  Electric and magnetic field characteristics of discrete arcs in the polar cap , 1982 .

[28]  J. Ruohoniemi,et al.  Electric potential patterns deduced for the SUNDIAL period of September 23-26, 1986 , 1990 .

[29]  Huiling Li,et al.  Magnetic properties of hematite in lava flows from Iceland: Response to hydrothermal alteration , 1993 .

[30]  A. Miura Anomalous transport by magnetohydrodynamic Kelvin‐Helmholtz instabilities in the solar wind‐magnetosphere interaction , 1984 .

[31]  B. Sonnerup Theory of the low-latitude boundary layer , 1980 .

[32]  G. Siscoe,et al.  IMF By and day‐night conductivity effects in the expanding polar cap convection model , 1987 .

[33]  L. Frank,et al.  Low‐energy electron intensities at large distances over the Earth's polar cap , 1976 .

[34]  T. Hill Solar-Wind Magnetosphere Coupling , 1983 .

[35]  L. Lyons,et al.  Energetic and magnetosheath energy particle signatures of the low-latitude boundary layer at low altitudes near noon , 1992 .

[36]  T. Hill Rates of mass, momentum, and energy transfer at the magnetopause , 1979 .

[37]  N. Crooker Mapping the merging potential from the magnetopause to the ionosphere through the dayside cusp , 1988 .

[38]  Timothy Fuller-Rowell,et al.  Height-integrated Pedersen and Hall conductivity patterns inferred from the TIROS-NOAA satellite data , 1987 .

[39]  L. Blomberg,et al.  On the influence of localized electric fields and field‐aligned currents associated with polar arcs on the global potential distribution , 1991 .

[40]  Arthur D. Richmond,et al.  Mapping electrodynamic features of the high-latitude ionosphere from localized observations: technique , 1988 .

[41]  Patrick T. Newell,et al.  Mapping the dayside ionosphere to the magnetosphere according to particle precipitation characteristics , 1992 .

[42]  G. Siscoe,et al.  Polar cap inflation and deflation , 1985 .

[43]  I. McCrea,et al.  Electrodynamic patterns for September 19, 1984 , 1989 .

[44]  Lou‐Chuang Lee,et al.  Coupling of magnetopause-boundary layer to the polar ionosphere , 1993 .

[45]  G. Mcgill,et al.  Evidence for a complex archean deformational history; southwestern Michipicoten Greenstone Belt, Ontario , 1986 .

[46]  Nancy U. Crooker,et al.  Dayside merging and cusp geometry , 1979 .

[47]  C. E. Rasmussen,et al.  An Interplanetary Magnetic Field Dependent Model of the Ionospheric Convection Electric Field , 1986 .

[48]  P. Reiff Sunward convection in both polar caps , 1982 .

[49]  Y. Kamide,et al.  Electric conductivities, electric fields and auroral particle energy injection rate in the auroral ionosphere and their empirical relations to the horizontal magnetic disturbances , 1983 .

[50]  N. Maynard,et al.  Consequences of using simple analytical functions for the high-latitude convection electric field , 1989 .

[51]  R. Hoffman,et al.  Electrodynamic patterns in the polar region during periods of extreme magnetic quiescence , 1988 .

[52]  Arthur D. Richmond,et al.  Assimilative mapping of ionospheric electrodynamics , 1992 .

[53]  R. Heelis,et al.  A model for multiple throat structures in the polar cap flow entry region , 1988 .

[54]  C. Senior,et al.  Global measures of ionospheric electrodynamic activity inferred from combined incoherent scatter radar and ground magnetometer observations , 1990 .

[55]  M. Kivelson,et al.  Kelvin‐Helmholtz Instability at the magnetopause: Energy flux into the magnetosphere , 1983 .

[56]  E. Friis-christensen,et al.  Electric Field and Current Coupling at High Latitudes , 1991 .

[57]  R. Heelis,et al.  IMF By ‐dependent plasma flow and Birkeland currents in the dayside magnetosphere: 1. Dynamics Explorer observations , 1985 .

[58]  D. Southwood Magnetopause Kelvin-Helmholtz instability , 1979 .

[59]  Y. Kamide,et al.  Interplanetary magnetic field control of high-latitude electric fields and currents determined from Greenland Magnetometer Data , 1985 .

[60]  C. E. Rasmussen,et al.  Ionospheric convection driven by NBZ currents , 1987 .

[61]  R. Lundin,et al.  Boundary layer plasmas as a source for high-latitude, early afternoon, auroral arcs , 1985 .

[62]  R. M. Robinson,et al.  On calculating ionospheric conductances from the flux and energy of precipitating electrons , 1987 .

[63]  R. Greenwald,et al.  Simultaneous conjugate observations of dynamic variations in high‐latitude dayside convection due to changes in IMF By , 1990 .

[64]  C. Meng,et al.  Intense uniform precipitation of low‐energy electrons over the polar cap , 1977 .

[65]  P. Reiff,et al.  IMF By-dependent plasma flow and Birkeland currents in the dayside magnetosphere: 2. A global model for northward and southward IMF , 1985 .

[66]  A. Lui,et al.  By -dependent convection patterns during northward interplanetary magnetic field , 1984 .

[67]  J. Luhmann,et al.  Solar Wind Control of the Polar CAP Voltage , 1986 .

[68]  R. Lundin,et al.  The contribution of the boundary layer EMF to magnetospheric substorms, in magnetospheric substorms , 2013 .

[69]  R. Heelis The effects of interplanetary magnetic field orientation on dayside high‐latitude ionospheric convection , 1984 .