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Three Species Collisionless Reconnection: Effect of O + on Magnetotail Reconnection. Michael Shay – Univ. of Maryland Preprints at: http://www.glue.umd.edu/~shay/papers. Overview. 3-species reconnection What length scales? Signatures? Reconnection rate? Examples and background - PowerPoint PPT Presentation
Three Species Collisionless Reconnection: Effect of O+ on
Magnetotail Reconnection
Michael Shay – Univ. of Maryland
Preprints at: http://www.glue.umd.edu/~shay/papers
Overview
• 3-species reconnection– What length scales? – Signatures?– Reconnection rate?
• Examples and background
• Linear theory of 3-species waves
• 3-Fluid simulations
Magnetospheric O+
• Earth’s magnetosphere– ionospheric outflows can lead to
significant O+ population.
– Active Times
• Oct. 1, 2001: Geomagnetic storm– CLUSTER, spacecraft 4
– CIS/CODIF data
– More O+ than protons.
– Chicken or Egg?
March 18, 2002
Astrophysical Plasmas
• Star and planet forming regions– Molecular clouds and
protoplanetary disks.
– Lots of dust.
– Wide range of conditions.
• Dust– negatively charged
– mass >> proton mass.
• Collisions with neutrals important also.
Hubble Orion Nebula Panorama
Previous Computational Work
• Birn et al. (2001, 2004)– Global MHD magnetotail simulations. – Test particle O+ to examine acceleration and beam
generation.
• Winglee et al. (2002, 2004)– Global MHD 2-fluid magnetospheric simulations.– Reduction of cross polar cap potential.– Did not resolve inner reconnection scales.
• Hesse et al., 2004– 3-species full particle simulations.– O+ had no effect on reconnection, although an increase in
proton density did.– Simulation size not large enough to fully couple O+.
Three-Fluid Equations
*
and
, { , }
( )
( )
( ),
e e i i h h h e i h h
i ii h h e h i e
e
h h hh h h h h e h e
e
e
n n z n n n z n
nn i h
td n
n z n P Pdt n
d z nm n z n P P
dt n
t
V V V J
V
VV V B J B
VV V B
BV B J B
• Three species: {e,i,h} = {electrons, protons, heavy species}
• mh* = mh/mi
• Normalize: t0 = 1/i and L0 = di c/pi
• E = Ve B Pe/ne
1D Linear waves
• Examine linear waves– Assume k || Bo
– Compressional modes decouple.
-Z
Y
X
Vin
Vou
t
Dispersion Relation
Slow Alfven
• h
• 2nd and 4th terms
3 22 2 2 2 2 2
3 2
2
1 0
/
h h h h h h h hs s s
i i i i i i i i i
s i i e
z n z nk d k d k d
n n
d d n n
2
2
4
At
Ath h i i
k c
Bc
m n m n
Fast Waves
• h, i >> h
22 2 2 2
20h h
s si i
z nk d k d
n
3-Species Waves: Magnetotail Lengths
• Previous Astrophysical Work.
• Heavy dust whistler (nh << ni, mhnh >> mini) has been examined but not in the context of reconnection.
• Shukla et al, 1997.
• Rudakov et al., 2001.
• Ganguli et al., 2004.
2 22000kmi e
ih h
n nd
z n800kmi
ie
nd
n 5000kmhd
Heavy Alfve
=
n
Ahk c2
Heavy Whistler
= h Ahk d c
Light A
=
lfven
iAi
e
nk c
n
2
Light Whis
=
tler
ii Ai
e
nk d c
n
Smaller Larger
ni = 0.05 cm-3
no+/ni = 0.64
d = c/p
Heavy Whistler
• Assume:– Vh << Vi,Ve
– Ignore ion inertia => Vi Ve
( ) ( )eh hnt t z
B JV B B
B
hi h hi
h e hz znt
nd
nd
V JB VV
B B
22 2i e
iz h
n ndz n 1 dh
The Nature of Heavy Whistlers1. Heavy species is unmagnetized and almost unmoving.
2. Primary current consists of frozen-in ions and electrons E B drifting.Ions+Electron fluid has a small net charge: charge density = e zh nh.
3. This frozen-in current drags the magnetic field along with it.
Z
Y
-X
Frozen-in Ion/Electron current
Z
Y
-X
Effect on Reconnection?• Dissipation region
– 3-4 scale structure.
• Reconnection rate– Vin ~ /D Vout
– Vout ~ CAt
• CAt = [ B2/4(nimi + nhmh) ]1/2
– nhmh << nimi
• Slower outflow, slower reconnection.
• Signatures of reconnection– Quadrupolar Bz out to much larger scales.
– Parallel Hall Ion currents• Analogue of Hall electron currents.
VinVout
y
xz
Simulations: Heavy Ions
• 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.
• me = 0.0, 44B term breaks frozen-in, 4 = 5 • 10-5
• Time normalized to i-1, Length to di c/pi.
• Isothermal approximation, = 1
VinCA
z
xy
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
Equilibrium• Double current sheet
– Double tearing mode.
• Harris equilibrium– Te = Ti
– Ions and electrons carry current.
• Background heavy ion species.– nh = 0.64.– Th = 0.5– mh = {1,16,104}– dh = {1,5,125}
• Seed system with x-lines.• Note that all differences in cAt is
due to mass difference.
Z
Z
Z
Jz
Bx
dens
ity Electrons
Ions
Heavy Ions
nVz
2-Fluid case mh* = 1
• Quadrupolar By
– about di scale size.
• Vix = Vhx
By with proton flow vectors
Vix with B-field lines.
Vhx
X
Z
X
Z
X
Z
• Quadrupolar By
– Both light and heavy whistler.
• Vi participates in Hall currents.
• Vhx acts like Vix in two-fluid case.
X
Z
Z
Light Whistler
Heavy Whistler
By with proton flow vectors
Vix with B-field lines.
Vhx
O+ Case: mh* = 16
• Quadrupolar By
– System size heavy whistler.
• Vix – Global proton hall
currents.
• Vhx basically immovable.
By with proton flow vectors
Vix with B-field lines.
Vhx
Whistler dominated mh* = 104
Reconnection Rate• Reconnection rate is
significantly slower for larger heavy ion mass.
– nh same for all 3 runs. This effect is purely due to mh..
• Slowdown in mh* = 104?
• System size scales:– Alfven wave: V cAh
– Whistler: V k dh cAh
V dh cAh/L
=> As island width increases, global speed decreases.
mh* = 1mh* = 16mh* = 104
Reconnection Rate
Island WidthTime
Time
Key SignaturesO+ Case
• Heavy Whistler– Large scale quadrupolar By
– Ion flows • Ion flows slower.
• Parallel ion streams near separatrix.
• Maximum outflow not at center of current sheet.
– Electric field?
By
Cut through x=55
Cut through x=55
Vel
ocit
y
mh* = 1mh* = 16
proton Vx
O+ Vx
mh* = 16
Z
Z
symmetry axis
X
ZLight Whistler
Heavy Whistler
Physical Regions
• Cuts through x-line along outflow direction.– Inner regions substantially
compressed for mh* = 104.
– Vix minimum.
light whistler
light Alfven
heavy whistler heavy Alfven
Vex
Vix
Vhx
X
X
Z
Z
Z
X
Vex
Vix
light whistler light Alfven
heavy whistler
mh* = 1
mh* = 16
mh* = 104
Scaling of Outflow speed
• Maximum outflow speed– mh* = 1: Vout1 1.0
– mh* = 16: Vout16 0.35
• Expected scaling:– Vout cAt CAt = [ B2/4(nimi + nhmh) ]1/2
• Vout1/Vout16 2.9
• cAt1/cAt16 2.6
Consequences for magnetotail reconnection
• When no+mo+ > ni mi
– Slowdown of outflow normalized to upstream cAi
– Slowdown of reconnection rate normalized to upstream cAi.
• However:– Strongly dependent on lobe Bx.
– Strongly active times: cAi may change dramatically.
Specific Signatures: O+ Modified Reconnection
• O+ outflow at same speed as proton outflow.– Reduction of proton flow.
• Larger scale quadrupolar By (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.
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, …
Conclusion• 3-Species reconnection: New hierarchy of scales.
– 3-4 scale structure dissipation region.– Heavy whistler
• Reconnection rate– Vin ~ /D Vout
– Vout ~ CAt
• CAt = [ B2/4(nimi + nhmh) ]1/2
– nhmh << nimi • Slower outflow, slower reconnection.
• Signatures of reconnection– Quadrupolar Bz out to much larger scales. – Parallel Hall Ion currents
• Analogue of Hall electron currents.
