Presentation is loading. Please wait.

Presentation is loading. Please wait.

Ionospheric Convection and Field-Aligned Currents During Strong Magnetospheric Driving: A SuperDARN/AMPERE Case Study L. B. N. Clausen (1), J. B. H. Baker.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Ionospheric Convection and Field-Aligned Currents During Strong Magnetospheric Driving: A SuperDARN/AMPERE Case Study L. B. N. Clausen (1), J. B. H. Baker."— Presentation transcript:

1 Ionospheric Convection and Field-Aligned Currents During Strong Magnetospheric Driving: A SuperDARN/AMPERE Case Study L. B. N. Clausen (1), J. B. H. Baker (1), J. M. Ruohoniemi (1), B. J. Anderson (2) (1)Space@VT, Virginia Tech, Blacksburg, USA (2)Johns Hopkins University Applied Physics Laboratory, Laurel, USA SuperDARN Workshop 2011

2 Slide Title Name (Space@VT)Short Presentation TitleMeeting, Date Section Name Subsection name Introduction

3 AMPERE Overview Introduction Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 The Active Magnetosphere and Planetary Electrodynamics Response Experiment (AMPERE) is based on the constellation of Iridium® Communications satellites. The Iridium® constellation consists of >66 satellites in six 780-km altitude, circular polar orbit planes. Each satellite carries a magnetometer!

4 AMPERE Overview Introduction Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Consider line current perpendicular to satellite motion Current creates magnetic field Satellite measures magnetic perturbation. Reconstruct current from magnetic perturbation: curl B = μ 0 j

5 AMPERE Overview Introduction Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Anderson et al., 2010 But Iridium® magnetometers are engineering magnetometers, used for attitude control: Low resolution: 30 nT Low time cadence: 200 s/sample

6 AMPERE Overview Introduction Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Korth et al., 2008

7 AMPERE Overview Introduction Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Anderson et al., 2010 Ampere provides high-time resolution measurements of the magnetic perturbation 20 s/sample 2 s/sample

8 FACs Introduction Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Field-aligned currents are a crucial element in magnetosphere- ionosphere coupling All currents in the magnetosphere- ionosphere system are divergence free Field-aligned currents close via Pedersen currents in the ionosphere

9 Solar Wind Conditions Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Geotail was located 5 Re upstream of the bow shock The data are lagged by 15 minutes Northward IMF was followed by southward IMF

10 SuperDARN & AMPERE Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011

11 SuperDARN & AMPERE Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011

12 SuperDARN & AMPERE Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011

13 SuperDARN & AMPERE Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011

14 SuperDARN & AMPERE Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011

15 Locating FACs Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Extract FAC intensity at each MLT Fit a suitable function to each meridional profile Combine locations from all meridional profiles to get a hemispheric FAC location

16 Locating FACs Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Extract FAC intensity at each MLT Fit a suitable function to each meridional profile Combine locations from all meridional profiles to get a hemispheric FAC location

17 Locating FACs Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 Extract FAC intensity at each MLT Fit a suitable function to each meridional profile Combine locations from all meridional profiles to get a hemispheric FAC location

18 FAC in Motion Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 During northward IMF R1 & R2 currents are weak, so that the fitting fails During southward IMF the currents intensify and fitting is more reliant Due to magnetic flux being opened on the dayside, the polar cap expands and with it the FAC locations

19 Velocity Shear Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 The radar at Stokkseyri observed strong velocity shears during the period of southward IMF

20 Velocity Shear vs. FAC Motion Observations Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011 The radar at Stokkseyri observed strong velocity shears during the period of southward IMF These shears are co- located with the center of the FACs as observed by AMPERE The motion of the velocity shear is very close to the motion of the currents

21 Conclusions AMPERE provide high time resolution observations of the field-aligned currents Dayside reconnection causes the polar cap to expand and the FACs move equatorward Co-located with the strongest FACs strong velocity shears are observed Lasse Clausen (Space@VT)SuperDARN/AMPERE studySD Workshop, June 2011

22 Slide Title Name (Space@VT)Short Presentation TitleMeeting, Date Section Name Subsection name

Download ppt "Ionospheric Convection and Field-Aligned Currents During Strong Magnetospheric Driving: A SuperDARN/AMPERE Case Study L. B. N. Clausen (1), J. B. H. Baker."

Similar presentations

SuperDARN is a network of HF radars (8-20 MHz) used to study the convection in the Earth's ionosphere at altitudes between 90 and 400 km and at magnetic.

SuperDARN is a network of HF radars (8-20 MHz) used to study the convection in the Earth's ionosphere at altitudes between 90 and 400 km and at magnetic.
Generation of the transpolar potential Ramon E. Lopez Dept. of Physics UT Arlington.

Generation of the transpolar potential Ramon E. Lopez Dept. of Physics UT Arlington.
No. 1 Characteristics of field-aligned currents derived from the Swarm constellation Hermann Lühr, Jaeheung Park, Jan Rauberg, Ingo Michaelis, Guram Kervalishvili.

No. 1 Characteristics of field-aligned currents derived from the Swarm constellation Hermann Lühr, Jaeheung Park, Jan Rauberg, Ingo Michaelis, Guram Kervalishvili.
Principles of Global Modeling Paul Song Department of Physics, and Center for Atmospheric Research, University of Massachusetts Lowell Introduction Principles.

Principles of Global Modeling Paul Song Department of Physics, and Center for Atmospheric Research, University of Massachusetts Lowell Introduction Principles.
Formation of the Magnetosphere 1 Solar Wind. Formation of the Magnetosphere 2 Solar Wind Bow Shock Magnetosheath.

Formation of the Magnetosphere 1 Solar Wind. Formation of the Magnetosphere 2 Solar Wind Bow Shock Magnetosheath.
The role of solar wind energy flux for transpolar arc luminosity A.Kullen 1, J. A. Cumnock 2,3, and T. Karlsson 2 1 Swedish Institute of Space Physics,

The role of solar wind energy flux for transpolar arc luminosity A.Kullen 1, J. A. Cumnock 2,3, and T. Karlsson 2 1 Swedish Institute of Space Physics,
VT SuperDARN Group2011 SuperDARN WorkshopJoseph Baker Testing the Equipotential Magnetic Field Line Assumption Using Interhemispheric.

VT SuperDARN Group2011 SuperDARN WorkshopJoseph Baker Testing the Equipotential Magnetic Field Line Assumption Using Interhemispheric.
Solar wind-magnetosphere coupling, substorms, and ramifications for ionospheric convection Steve Milan Adrian Grocott (Leics,

Solar wind-magnetosphere coupling, substorms, and ramifications for ionospheric convection Steve Milan Adrian Grocott (Leics,
Peter Boakes 1, Steve Milan 2, Adrian Grocott 2, Mervyn Freeman 3, Gareth Chisham 3, Gary Abel 3, Benoit Hubert 4, Victor Sergeev 5 Rumi Nakamura 1, Wolfgang.

Peter Boakes 1, Steve Milan 2, Adrian Grocott 2, Mervyn Freeman 3, Gareth Chisham 3, Gary Abel 3, Benoit Hubert 4, Victor Sergeev 5 Rumi Nakamura 1, Wolfgang.
Comparing the solar wind-magnetosphere interaction at Mercury and Saturn A. Masters Institute of Space and Astronautical Science, Japan Aerospace Exploration.

Comparing the solar wind-magnetosphere interaction at Mercury and Saturn A. Masters Institute of Space and Astronautical Science, Japan Aerospace Exploration.
Figure 4: Overview of the geometry of the Rankin Inlet and Inuvik radar in MLT coordinates on Aug 08 th 2010. Merged vectors are shown in black. AMPERE.

Figure 4: Overview of the geometry of the Rankin Inlet and Inuvik radar in MLT coordinates on Aug 08 th Merged vectors are shown in black. AMPERE.
Auroral dynamics EISCAT Svalbard Radar: field-aligned beam  complicated spatial structure (

Auroral dynamics EISCAT Svalbard Radar: field-aligned beam  complicated spatial structure (
AJ Ribeiro Irregs.Short Meeting Title, Date A survey of plasma irregularities seen by the mid-latitude Blackstone SuperDARN radar.

AJ Ribeiro Irregs.Short Meeting Title, Date A survey of plasma irregularities seen by the mid-latitude Blackstone SuperDARN radar.
Phase Coherence on Open Field Lines Associated with FLRs Abiyu Nedie, Frances Fenrich & Robert Rankin University of Alberta Edmonton, Alberta, Canada 2011.

Phase Coherence on Open Field Lines Associated with FLRs Abiyu Nedie, Frances Fenrich & Robert Rankin University of Alberta Edmonton, Alberta, Canada 2011.
On the relationship between polar cap flows and the IMF W.A. Bristow, R.T. Parris, J. Spaleta, T. Theurer Geophysical Institute, University of Alaska.

On the relationship between polar cap flows and the IMF W.A. Bristow, R.T. Parris, J. Spaleta, T. Theurer Geophysical Institute, University of Alaska.
State Key Laboratory of Space Weather An inter-hemisphere asymmetry of the cusp region against the geomagnetic dipole tilt Jiankui Shi Center for Space.

State Key Laboratory of Space Weather An inter-hemisphere asymmetry of the cusp region against the geomagnetic dipole tilt Jiankui Shi Center for Space.
Ionospheric Convection Response to High-Latitude Reconnection and Electrodynamics of a Split-Transpolar Aurora S. Eriksson 1, G. Provan 2, F. J. Rich 3,

Ionospheric Convection Response to High-Latitude Reconnection and Electrodynamics of a Split-Transpolar Aurora S. Eriksson 1, G. Provan 2, F. J. Rich 3,
On the importance of IMF |B Y | on polar cap patch formation Qinghe Zhang 1, Beichen Zhang 1, Ruiyuan Liu 1, M. W. Dunlop 2, M. Lockwood 2, 3, J. Moen.

On the importance of IMF |B Y | on polar cap patch formation Qinghe Zhang 1, Beichen Zhang 1, Ruiyuan Liu 1, M. W. Dunlop 2, M. Lockwood 2, 3, J. Moen.
Radio and Space Plasma Physics Group The formation of transpolar arcs R. C. Fear and S. E. Milan University of Leicester.

Radio and Space Plasma Physics Group The formation of transpolar arcs R. C. Fear and S. E. Milan University of Leicester.
Auroral Boundaries Model Validation – What has been done.

Auroral Boundaries Model Validation – What has been done.

Similar presentations

Ads by Google