Presentation is loading. Please wait.

Presentation is loading. Please wait.

Magnetosphere-Ionosphere Coupling through Plasma Turbulence at High- Latitude E-Region Electrojet Y. Dimant and M. Oppenheim Tuesday, April 13, 2010 Center.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Magnetosphere-Ionosphere Coupling through Plasma Turbulence at High- Latitude E-Region Electrojet Y. Dimant and M. Oppenheim Tuesday, April 13, 2010 Center."— Presentation transcript:

1 Magnetosphere-Ionosphere Coupling through Plasma Turbulence at High- Latitude E-Region Electrojet Y. Dimant and M. Oppenheim Tuesday, April 13, 2010 Center for Space Physics, Boston University Dynamical Processes in Space Plasmas Israel, 10-17 April 2010

2 Outline Background and motivation Anomalous electron heating Nonlinear current; energy deposition 3-D and 2-D fully kinetic modeling of E-region instabilities Anomalous conductivity Conclusions; future work

3 Solar Corona Solar Wind Ionosphere Magnetosphere Inner Boundary for Solar-Terrestrial System

4 Earth’s Ionosphere

5 What’s going on? Field-aligned (Birkeland) currents along equipotential magnetic field lines flow in and out. Mapped DC electric fields drive high-latitude electrojet (where Birkeland currents are closed). Strong fields also drive E-region instabilities: turbulent field coupled to density irregularities. –Turbulent fields give rise to anomalous heating. –Density irregularities create nonlinear currents. These processes can affect macroscopic ionospheric conductances important for Magnetosphere- Ionosphere current system.

6 Motivation How magnetospheric energy gets deposited in the lower ionosphere? Global magnetospheric MHD codes with normal conductances often overestimate the cross-polar cap potential (about a factor of two). Anomalous conductance due to E-region turbulence can account for discrepancy!

7 Strong electron heating Reproduced from Foster and Erickson, 2000 125 mV/m

8 (Reproduced from Stauning & Olesen, 1989)

9 Anomalous Electron Heating (AEH) Anomalous heating: Normal ohmic heating by E 0 cannot account in full measure. Farley-Buneman, etc. instabilities generate  E. Heating by major turbulent-field components  E   B is not sufficient. Small  E || || k || || B, |  E || |<<|  E  |, are crucial: –Confirmed by recent 3-D PIC simulations.

10 Analyitical Model of AEH Dimant & Milikh, 2003: –Heuristic model of saturated FB turbulence (HMT), –Kinetic simulations of electron distribution function. Difficult to validate HMT by observations: –Radars: Pro: Can measure k || (aspect angle ~ 1 o ), Con: Only one given wavelength along radar LOS. –Rockets: Pro: Can measure full spectrum of density irregularities and fields, Con: Hard to measure E || ; other diagnostic problems. Need advanced and trustworthy 3-D simulations!

11

12 PIC simulations: electron density E 0 x B direction E 0 direction

13 3D simulations 256x256x512 Grid256x256x512 Grid Lower Altitude (more collisional)Lower Altitude (more collisional) Driving Field: ~4x Threshold field (150 mV/m at high latitudes)Driving Field: ~4x Threshold field (150 mV/m at high latitudes) Artificial e - mass: m e:sim = 44m e ;Artificial e - mass: m e:sim = 44m e ; ExB direction (m) E 0 direction (m) B 0 direction (m) 0 0 102 0 0 410 Potential (x-y cross-section) Potential (x-z cross-section) 4 Billion virtual PIC particles 4 Billion virtual PIC particles 2D looks the same! 2D looks the same!

14 Higher altitude 3D simulation Ions: First Moment (RMS Of V i ) electrons: First Moment (RMS Of V e ) 3-D Temps 2-D Temps

15 Anomalous heating [Milikh and Dimant, 2003] E = 82 mV/m (comparison with Stauning and Olesen [1989])

16 Cross-polar cap potential (Merkin et al. 2005)

17 Anomalous Electron Heating (AEH) Affects conductance indirectly: –Reduces recombination rate, –Increases density. All conductivities change in proportion. Inertia due to slow recombination changes: –Smoothes and reduces fast variations. Can account only for a fraction of discrepancy. Need something else, but what?

18 Nonlinear current (NC) Direct effect of plasma turbulence: –Caused by density irregularities,  n. Only needs developed plasma turbulence – no inertia and time delays. Increases Pedersen conductivity (|| E 0 ) –Crucial for MI coupling! Responsible for the total energy input, including AEH.

19 Characteristics of E-region waves Electrostatic waves nearly perpendicular to Low-frequency, E-region ionosphere (90-130km): dominant collisions with neutrals - Magnetized electrons: - Demagnetized ions: Driven by strong DC electric field, Damped by collisional diffusion (ion Landau damping for FB)

20 electrons ions Two-stream conditions (magnetized electrons + unmagnetized ions)

21 Wave frame of reference _ + _ + ___ + +++ ___ + +++ + ____ IonsElectrons

22 Nonlinear Current

23 Mean Turbulent Energy Deposit Work by E 0 on the total nonlinear current Buchert et al. (2006): –Essentially 2-D treatment, –Simplified plasma and turbulence model. Confirmed from first principles. Calculated NC and partial heating sources: –Full 3-D turbulence, –Arbitrary particle magnetization, –Quasi-linear approximation using HMT.

24 Anomalous energy deposition Nonlinear current: is total energy source for turbulence! How 2-D field and NC can provide 3-D heating? Density fluctuations in 3-D are larger than in 2-D!

25 3-D vs. 2-D, Densities

26 Nonlinear current (NC) Mainly, Pedersen current (in E 0 direction). May exceed normal Pedersen current. May reduce the cross-polar cap potential. Along with the anomalous-heating effect, should be added to conductances used in global MHD codes for Space Weather modeling

27 E-region turbulence and Magnetosphere-Ionosphere Coupling Anomalous electron heating, via temperature- dependent recombination, increases electron density. Increased electron density increases E-region conductivities. Nonlinear current directly increases mainly Pedersen conductivity. Both effects increase conductance and should lower cross polar cap potentials during magnetic storms. Could be incorporated into global MIT models.

28 Conclusions Theory & PIC simulations: E-region turbulence affects magnetosphere-ionosphere coupling: –(1) Anomalous electron heating, via temperature-dependent recombination, increases electron density. Increased electron density increases E-region conductivities. –(2) Nonlinear current directly increases electrojet Pedersen conductivity. Responsible for total energy input to turbulence. –Both anomalous effects increase conductance and should lower cross-polar cap potentials during magnetic storms. Will be incorporated into a global MHD model.

29 Fully Kinetic 2-D Simulations Simulations Parameters: Altitude ~101km in Auroral region Driving Field: ~1.5 Threshold field (50 mV/m at high latitudes) Artificial e - mass: m e:sim = 44m e ; m i:sim =m i 2-D Grid: 4024 cells of 0.04m by 4024 cells of 0.04m Perpendicular to geomagnetic field, B 8 Billion virtual PIC particles Timestep: dt =  s (< cyclotron and plasma frequencies) E 2 (V/m) 2 Time (s) ExB direction (m) E 0 direction (m)

30 Threshold electric field FB: Farley-Buneman instability IT: Ion thermal instability ET: Electron thermal instability CI: Combined (FB + IT + ET) instability 1: Ion magnetization boundary 2: Combined instability boundary High-latitude ionosphereEquatorial ionosphere [Dimant & Oppenheim, 2004]

31 3-D vs. 2-D, Temperatures 3-D Simulations get hotter!3-D Simulations get hotter! Electron Moments Ion Moments 3-D Temp 2-D Temp Time (s)

32 ‘5-moment’ transport equations Fluid-model equations for long-wavelength waves: they do not include heat conductivity, Landau damping, etc., but contain all essential factors.

Download ppt "Magnetosphere-Ionosphere Coupling through Plasma Turbulence at High- Latitude E-Region Electrojet Y. Dimant and M. Oppenheim Tuesday, April 13, 2010 Center."

Similar presentations

Magnetic Turbulence in MRX (for discussions on a possible cross-cutting theme to relate turbulence, reconnection, and particle heating) PFC Planning Meeting.

Magnetic Turbulence in MRX (for discussions on a possible cross-cutting theme to relate turbulence, reconnection, and particle heating) PFC Planning Meeting.
Session A Wrap Up. He Abundance J. Kasper Helium abundance variation over the solar cycle, latitude and with solar wind speed Slow solar wind appears.

Session A Wrap Up. He Abundance J. Kasper Helium abundance variation over the solar cycle, latitude and with solar wind speed Slow solar wind appears.
Electron Acceleration in the Van Allen Radiation Belts by Fast Magnetosonic Waves Richard B. Horne 1 R. M. Thorne 2, S. A. Glauert 1, N. P. Meredith 1.

Electron Acceleration in the Van Allen Radiation Belts by Fast Magnetosonic Waves Richard B. Horne 1 R. M. Thorne 2, S. A. Glauert 1, N. P. Meredith 1.
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.
Non-Resonant Quasilinear Theory Non-Resonant Theory.

Non-Resonant Quasilinear Theory Non-Resonant Theory.
Alfvén-cyclotron wave mode structure: linear and nonlinear behavior J. A. Araneda 1, H. Astudillo 1, and E. Marsch 2 1 Departamento de Física, Universidad.

Alfvén-cyclotron wave mode structure: linear and nonlinear behavior J. A. Araneda 1, H. Astudillo 1, and E. Marsch 2 1 Departamento de Física, Universidad.
Modelling the Thermosphere-Ionosphere Response to Space Weather Effects: the Problem with the Inputs Alan Aylward, George Millward, Alex Lotinga Atmospheric.

Modelling the Thermosphere-Ionosphere Response to Space Weather Effects: the Problem with the Inputs Alan Aylward, George Millward, Alex Lotinga Atmospheric.
Auroral dynamics EISCAT Svalbard Radar: field-aligned beam  complicated spatial structure (

Auroral dynamics EISCAT Svalbard Radar: field-aligned beam  complicated spatial structure (
Modeling Generation and Nonlinear Evolution of VLF Waves for Space Applications W.A. Scales Center of Space Science and Engineering Research Virginia Tech.

Modeling Generation and Nonlinear Evolution of VLF Waves for Space Applications W.A. Scales Center of Space Science and Engineering Research Virginia Tech.
Modeling Generation and Nonlinear Evolution of Plasma Turbulence for Radiation Belt Remediation Center for Space Science & Engineering Research Virginia.

Modeling Generation and Nonlinear Evolution of Plasma Turbulence for Radiation Belt Remediation Center for Space Science & Engineering Research Virginia.
The Structure of the Parallel Electric Field and Particle Acceleration During Magnetic Reconnection J. F. Drake M.Swisdak M. Shay M. Hesse C. Cattell University.

The Structure of the Parallel Electric Field and Particle Acceleration During Magnetic Reconnection J. F. Drake M.Swisdak M. Shay M. Hesse C. Cattell University.
Subionospheric VLF propagation

Subionospheric VLF propagation
12 00 12 00 0 2 3 4 1 Prob, % WinterSummer Probability of observing downward field-aligned electron energy flux >10 mW/m 2 in winter and summer hemispheres.

Prob, % WinterSummer Probability of observing downward field-aligned electron energy flux >10 mW/m 2 in winter and summer hemispheres.
Hybrid Simulation of Ion-Cyclotron Turbulence Induced by Artificial Plasma Cloud in the Magnetosphere W. Scales, J. Wang, C. Chang Center for Space Science.

Hybrid Simulation of Ion-Cyclotron Turbulence Induced by Artificial Plasma Cloud in the Magnetosphere W. Scales, J. Wang, C. Chang Center for Space Science.
MI Coupling Physics: Issues, Strategies, Progress William Lotko 1, Peter Damiano 1, Mike Wiltberger 2, John Lyon 1,2, Slava Merkin 3, Oliver Brambles 1,

MI Coupling Physics: Issues, Strategies, Progress William Lotko 1, Peter Damiano 1, Mike Wiltberger 2, John Lyon 1,2, Slava Merkin 3, Oliver Brambles 1,
Computational Modeling Capabilities for Neutral Gas Injection Wayne Scales and Joseph Wang Virginia Tech Center for Space Science and Engineering.

Computational Modeling Capabilities for Neutral Gas Injection Wayne Scales and Joseph Wang Virginia Tech Center for Space Science and Engineering.
Ionospheric Electric Field Variations during Geomagnetic Storms Simulated using CMIT W. Wang 1, A. D. Richmond 1, J. Lei 1, A. G. Burns 1, M. Wiltberger.

Ionospheric Electric Field Variations during Geomagnetic Storms Simulated using CMIT W. Wang 1, A. D. Richmond 1, J. Lei 1, A. G. Burns 1, M. Wiltberger.
Carlson et al. ‘01 Three Characteristic Acceleration Regions.

Carlson et al. ‘01 Three Characteristic Acceleration Regions.
The tribulations and exaltations in coupling models of the magnetosphere with ionosphere- thermosphere models Aaron Ridley Department of Atmospheric, Oceanic.

The tribulations and exaltations in coupling models of the magnetosphere with ionosphere- thermosphere models Aaron Ridley Department of Atmospheric, Oceanic.
Incorporating Kinetic Effects into Global Models of the Solar Wind Steven R. Cranmer Harvard-Smithsonian Center for Astrophysics.

Incorporating Kinetic Effects into Global Models of the Solar Wind Steven R. Cranmer Harvard-Smithsonian Center for Astrophysics.

Similar presentations

Ads by Google