Presentation is loading. Please wait.

Presentation is loading. Please wait.

Magnetic Reconnection in Multi-Fluid Plasmas Michael Shay – Univ. of Maryland.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Magnetic Reconnection in Multi-Fluid Plasmas Michael Shay – Univ. of Maryland."— Presentation transcript:

1 Magnetic Reconnection in Multi-Fluid Plasmas Michael Shay – Univ. of Maryland

2 Magnetic Reconnection in Multi-Fluid Plasmas General Theory and Simulations of O + Modified Reconnection. Michael Shay – Univ. of Maryland

3 Background 2-species 2D reconnection has been substantially studied. Many plasma have 3 or more charged species. –Magnetotail: O + due to ionospheric outflows: CLUSTER CIS/CODIF (kistler) n o+ >> n i sometimes, especially during active times. –Astrophysical plasmas Dust species present Neutrals also. What will reconnection look like? –What length scales? Signatures? –Reconnection rate? Previous work –Global 3-fluid magnetospheric codes (Winglee). –Tracer particle stepping in global MHD models (Birn). –Full particle codes (Hesse).

4 Three-Fluid Equations Three species: {e,i,h} = {electrons, protons, heavy ions} m h* = m h /m i Normalize: t 0 = 1/  i and L 0 = d i  c/  pi E =  V e  B   P e /n e

5 1D Linear waves Examine linear waves –Assume k || B o –Compressional modes decouple. -Z Y X V in V out 

6 3-Species Waves: Magnetotail Lengths Heavy whistler: Heavy species are unmoving and unmagnetized. Electrons and ions frozen-in => Flow together. But, their flow is a current. Acts like a whistler. Heavy Alfven wave All 3 species frozen in. SmallerLarger n i = 0.05 cm -3 n o+ /n i = 0.64 d   = c/  p 

7 Effect on Reconnection Dissipation region –3-4 scale structure. Reconnection rate –V in ~  /D V out –V out ~ C At C At = [ B 2 /4  (n i m i + n h m h ) ] 1/2 –n h m h << n i m i Slower outflow, slower reconnection. Signatures of reconnection –Quadrupolar B z out to much larger scales. –Parallel Hall Ion currents Analogue of Hall electron currents. V in V out y x z

8 The Simulations Initial conditions: –No Guide Field. –Reconnection plane: (x,y) => Different from GSM – 2048 x 1024 grid points 204.8 x 102.4 c/  pi.  x =  y = 0.1 Run on 64 processors of IBM SP. m e = 0.0,  4  4 B term breaks frozen-in,  4 = 5 10 -5 Time normalized to  i -1, Length to d i  c/  pi. Isothermal approximation,  = 1 V in CACA y x z

9 Reconnection Simulations Double current sheet –Reconnects robustly Initial x-line perturbation X X X X Y Y Current along Z Density t = 0 t = 1200

10 Equilibrium Double current sheet –Double tearing mode. Harris equilibrium –T e = T i –Ions and electrons carry current. Background heavy ion species. –n h = 0.64. –T h = 0.5 –m h = {1,16,10 4 } –d h = {1,5,125} Seed system with x-lines. Y Y Y JzJz BxBx density Electrons Ions Heavy Ions nV z

11 Out-of-plane B m h* = 1 –Usual two-fluid reconnection. m h* = 16 –Both light and heavy whistler. –Parallel ion beams Analogue of electron beams in light whistler. m h* = 10 4 –Heavy Whistler at global scales. X X Z Z Z B y with proton flow vectors Light Whistler Heavy Whistler X

12 Reconnection Rate Reconnection rate is significantly slower for larger heavy ion mass. –n h same for all 3 runs. This effect is purely due to m h.. Eventually, the heavy whistler is the slowest. m h* = 1 m h* = 16 m h* = 10 4 Reconnection Rate Island Width Time

13 Key Signatures O + Case Heavy Whistler –Large scale quadrupolar B y –Ion flows Ion flows slower. Parallel ion streams near separatrix. Maximum outflow not at center of current sheet. –Electric field? ByBy Cut through x=55 Velocity m h* = 1 m h* = 16 proton V x O + V x m h* = 16 Z Z symmetry axis X Z Light Whistler Heavy Whistler

14 Outflow shows all 4 wave regions Outflow region –4 different physics regions Maximum outflow speed –m h* = 1: V out1  1.0 –m h* = 16: V out16  0.35 Expected scaling: –V out  c At C At = [ B 2 /4  (n i m i + n h m h ) ] 1/2 –V out1 /V out16  2.9 –c At1 /c At16  2.6 light whistler light Alfven heavy whistler heavy Alfven V ex V ix V hx X Cut through x-line along outflow

15 Consequences for magnetotail reconnection When n o+ m o+ > n i m i –Slowdown of outflow normalized to upstream c Ai –Slowdown of reconnection rate normalized to upstream c Ai. However: –Strongly dependent on lobe B x. –Strongly active times: c Ai may change dramatically.

16 Specific Signatures: O + Modified Reconnection O + outflow at same speed as proton outflow. –Reduction of proton flow. Larger scale quadrupolar B y (GSM). Parallel ion currents near the separatrices. –Upstream ions flow towards x-line. The CIS/CODIF CLUSTER instrument has the potential to examine these signatures.

17 Questions for the Future How is O + spatially distributed in the lobes? –Not uniform like in the simulations. How does O + affect the scaling of reconnection? –Will angle of separatrices (tan  D) change? Effect on onset of reconnection? Effect on instabilities associated with substorms? –Lower-hybrid, ballooning,kinking, …

Download ppt "Magnetic Reconnection in Multi-Fluid Plasmas Michael Shay – Univ. of Maryland."

Similar presentations

Progress and Plans on Magnetic Reconnection for CMSO For NSF Site-Visit for CMSO May1-2, 2005 1. Experimental progress [M. Yamada] -Findings on two-fluid.

Progress and Plans on Magnetic Reconnection for CMSO For NSF Site-Visit for CMSO May1-2, Experimental progress [M. Yamada] -Findings on two-fluid.
Three Species Collisionless Reconnection: Effect of O+ on Magnetotail Reconnection Michael Shay – Univ. of Maryland Preprints at: http://www.glue.umd.edu/~shay/papers.

Three Species Collisionless Reconnection: Effect of O+ on Magnetotail Reconnection Michael Shay – Univ. of Maryland Preprints at:
Particle acceleration in a turbulent electric field produced by 3D reconnection Marco Onofri University of Thessaloniki.

Particle acceleration in a turbulent electric field produced by 3D reconnection Marco Onofri University of Thessaloniki.
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.
Magnetic Structures in Electron-scale Reconnection Domain

Magnetic Structures in Electron-scale Reconnection Domain
Particle Simulations of Magnetic Reconnection with Open Boundary Conditions A. V. Divin 1,2, M. I. Sitnov 1, M. Swisdak 3, and J. F. Drake 1 1 Institute.

Particle Simulations of Magnetic Reconnection with Open Boundary Conditions A. V. Divin 1,2, M. I. Sitnov 1, M. Swisdak 3, and J. F. Drake 1 1 Institute.
William Daughton Plasma Physics Group, X-1 Los Alamos National Laboratory Presented at: Second Workshop on Thin Current Sheets University of Maryland April.

William Daughton Plasma Physics Group, X-1 Los Alamos National Laboratory Presented at: Second Workshop on Thin Current Sheets University of Maryland April.
The Many Scales of Collisionless Reconnection in the Earth’s Magnetosphere Michael Shay – University of Maryland.

The Many Scales of Collisionless Reconnection in the Earth’s Magnetosphere Michael Shay – University of Maryland.
Collisionless Magnetic Reconnection J. F. Drake University of Maryland Magnetic Reconnection Theory 2004 Newton Institute.

Collisionless Magnetic Reconnection J. F. Drake University of Maryland Magnetic Reconnection Theory 2004 Newton Institute.
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.
Max P. Katz, Wayne G. Roberge, & Glenn E. Ciolek Rensselaer Polytechnic Institute Department of Physics, Applied Physics and Astronomy.

Max P. Katz, Wayne G. Roberge, & Glenn E. Ciolek Rensselaer Polytechnic Institute Department of Physics, Applied Physics and Astronomy.
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.
Solar wind interaction with the comet Halley and Venus

Solar wind interaction with the comet Halley and Venus
Solar wind-magnetosphere coupling Magnetic reconnection In most solar system environments magnetic fields are “frozen” to the plasma - different plasmas.

Solar wind-magnetosphere coupling Magnetic reconnection In most solar system environments magnetic fields are “frozen” to the plasma - different plasmas.
Magnetic Explosions in Space: Magnetic Reconnection in Plasmas Michael Shay University of Delaware.

Magnetic Explosions in Space: Magnetic Reconnection in Plasmas Michael Shay University of Delaware.
Solar Flare Particle Heating via low-beta Reconnection Dietmar Krauss-Varban & Brian T. Welsch Space Sciences Laboratory UC Berkeley Reconnection Workshop.

Solar Flare Particle Heating via low-beta Reconnection Dietmar Krauss-Varban & Brian T. Welsch Space Sciences Laboratory UC Berkeley Reconnection Workshop.
The Diffusion Region of Asymmetric Magnetic Reconnection Michael Shay – Univ. of Delaware Bartol Research Institute.

The Diffusion Region of Asymmetric Magnetic Reconnection Michael Shay – Univ. of Delaware Bartol Research Institute.
SECTPLANL GSFC UMD The Collisionless Diffusion Region: An Introduction Michael Hesse NASA GSFC.

SECTPLANL GSFC UMD The Collisionless Diffusion Region: An Introduction Michael Hesse NASA GSFC.
Multifluid Simulations of the Magnetosphere. Final Equations Equations are not conservative except for the sum over all species Momentum is transferred.

Multifluid Simulations of the Magnetosphere. Final Equations Equations are not conservative except for the sum over all species Momentum is transferred.

Similar presentations

Ads by Google