dynamic current sheets - iii
TRANSCRIPT
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theunited nations
educational, scientificand culturalorganization
abdus salaminternational centre for theoretical physics
international atomicenergy agency
SMR 1331/18
AUTUMN COLLEGE ON PLASMA PHYSICS8 October - 2 November 2001
DYNAMIC CURRENT SHEETS - III
Lev Zelenyi
Russian Acedemy of Sciences, Space Research InstituteMoscow, Russia
These are preliminary lecture notes, intended only for distribution to participants.
strada costiera, I I - 34014 trieste italy - tel.+39 04022401 I I fax +39 040224163 - [email protected] - www.ictp.trieste.it
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I N T E R N A T I O N A ! A T O M I C E N E R G Y A G E N C Y
U N I T E D N A T I O N S EDUCAT I O N A L , S C I E N T I F I C A N D C U L T U R A L O R G A N I Z A T I O N
INTERNATIONAL CENTRE FOR THEORETICAL PHYSICSI.C.T.P., P.O. BOX 586, 34100 TRIESTE, ITALY, CABLE: CENTRATOM TRIESTE
Lecture 1.
CURRENT SHEETS IN SPACE PLASMA
Non adiabatic particle dynamics andnumerical simulations
Lecture 2.
EQUILIBRIUM CONFIGURATIONS OFFORCED SHEETS
Role of trapped and transient populations.
Lecture 3.
FRACTAL STRUCTURES IN CURRENT SHEETS
Multiscale turbulence and current branching
Acknowledgements:
UCLA MPAE, LindauV.Peroomian J.BuchnerM.Ashour-Abdalla
Maryland University Space Research InstituteD.Schriver A.GaleevM.Sitnov A.MilovanovS.Sharma H.Malova
E.GrigorenkoCalabria UniversityG.Zimbardo Georgian ObservatoryP.Veltri A.TaktakishviliA.Greko
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I N T E R N A T I o N A I. A T O M I C E N FI R G Y A G K N C Y
UNITED NATIONS EDUCATIONAL., SCIENTIFIC AND CULTURAL ORGANIZATION
INTERNATIONAL CENTRE FOR THEORETICAL PHYSICSI.C.T.P., P.O. BOX 586, 34100 TRIESTE, ITALY, CABLE: CENTRATOM TRIESTE
Lecture 3
FRACTAL STRUCTURES IN CURRENT SHEETS
1. Introduction: "Laminar" and "turbulent" sheets.
2. "Turbulence" in magnetotail1. Universality of power-low spectra.2. "Clumps" in plasma sheet.
3. Parameters of fractal distribution.1. Length (Hausdorff dimension).2. Spatial fractal dimension3. Index of connectivity4. Fractal dimension and Fourier spectra.
4. Self-consistent fractal model1. Diffusion on fractals.2. Effective cross-tail transport.3. Scaling of Maxwell equations.4. Percolation thresholds and Alexander-Orbach condition.5. Characteristics of "turbulence" and indexes of power law spectra.
5. Numerical model of particle transport in turbulent sheet1. Towards the pressure balance.2. Current splitting.3. Particle residence time
6. Structural stability of branched current network.
7. Conclusions: "Turbulence" as an intrinsic property of CS.
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Universality of the spectra of low-frequency magnetic "turbulence" in the near-Earth and distant parts of magnetotail
P(f)~F\ a (2*2.5)f (0 .01-1 Hz)
Kinks in the spectrum
B | ~ 104Gn ~ 1 cm'
AMPTE-CCE (Ohtani, 1995, 1998)AMPTE-IRM (Bauer, 1995)ISEE (Borovsky, 1998)
OQO-5 (Russell, 1972)
INTERBALL-1(Petrukovich, 1998)
GEOTAIL(Hoshino, 1994)
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HOSHINO ET AL TURBULENT PLASMA SHEET
. J!TO6O7 13VM15J «O6Z5 IMJ-I6I0 930(507 123OI2J5
10'fHi
Figure 2 Fourier Power spectral densities of Type C without bipolar gand Type B with bipolar signature (c) , observed by G EOT AIL The turnover Ofcontinuum appears around 0 04JElz. The model fitted spectra are plotted as dotte
OUTANI ET A L FRACTAL ANA1 Y t
Intprval ? (H Component) r i ,
tooo
100
0 1 1Frequency fHzl
Figure 4 Companson of ihe (top) fractal and (bottom)Foumr analyses for the H component during interval 2,froni 1152 45 to 1154 15 UT The dotted lines in the toppanel show the results of the two segment filting
" e t r u k o k n . f i "•
IT- - T [
-i.z.f X
.ju-l
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OHTANI ET AL.: FRACTAL ANALYSIS OF TAIL CURRENT DISRUPTION 49 9S 19,137
(a)For T < 1J4
1.0-
0.5-
x o.o-'
-0 5-
-1.0-1
(b)
1.
0.5 -I
X 0.0
-0.5-
-1.0-
10 12
Forx>Tc/4
10 30 40 50
Figure 1. Schematic illustrations of the measurement ofthe length of fluctuations, L{r), in cases in which r is (a)significantly shorter than and (b) the significant fraction ofthe characteristic time scale (period) of fluctuations.
AMPTE/CCE August 30 (Day 240), 1986
Figure '3. Expanded plot of the AMPTE/CCE magneto-meter data from 1152 to 1157 UT.
sets. Since in the Fourier analysis /*(/) is calculated for dis-crete values of/separated equally (A/ = (NAt)~i, where N isthe total number of data points), we do not have many datapoints in a low-frequency range. On the other hand, the fractalanalysis has no methodological restriction in selecting values oft, although the calculation of IX,T) is less stable for r closer tothe whole duration of the data interval. Since the region of tailcurrent disruption is spatially localized, the spacecraft does notremain in the disruption region for very long, and the dynamicsof a current sheet cause rapid motion of the spacecraft relativeto the spatial structure of signatures, resulting in abruptchanges in the phase of magnetic fluctuations. Thus these twopoints are cr'cial in examining current disruption.
3. Case Study: August 28, 1986, Event
3.1. Outline of the Event
An event we selected for a case study occurred on August28 (day 240), 1986. This event provides a unique opportunity,because the AMPTE/CCE satellite was in the disniption regionat a substorm onset and remained in the region for as long as 3min. The event was originally reported by Takahashi et al.[1987] and was examined later by Lui et al. [1992] andBurkhart el al. [1993] from different viewpoints.
Figure 2 shows a 20-min (1145-1205) plot of the AMPTE/CCE magnetometer data sampled every 0.124 s (see Potemra
AMPTE/CCE August 30 (Day 240), 1986
11:45 12:05
Figure 2. AMPTE/CCE magnetometer data from 1145 to1205 UT of the August 28, 1986, event. (Top to bottom)The V, D, and H magnetic components and the total fieldstrength. The horizontal bars in the H component panelrepresent the intervals we selected for the fractal analysis.
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O
I1I:
ml"
<D
o
CO
a
A
r'
O a:
ca1"
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Geometrical (FRACTAL) approach to magnetotail
jiigh (3 plasma
• "Turbulence" - ensemble of multiscale hierarchical
structures; consisting of magnetic CLUMPS and VOjDS -
i.e. is not SPACE Filling
• System reached the stage of NL self-consistent
SATURATION
(problem of "Turbulence" generation is BYPASSED)
All NL effects are accounted in the Geometry of the system
• In certain interval of scales QC<%<£> Geometry could
be considered as FRACTAL i.e. is Self-Similar.
Cross tail current Jy — <Jy> + 8 Jy is organized in
Percolating Network
Clumps <-» 5BZ <->SJy <Jy> <-> B o x - lobe field
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Coupled patterns of magne-totail current system and struc-tured turbulence
» Geometric analysis:Strong NL turbulence isintroduced into TOPOLOGYof tbe system.A l ; n . v h i n i r r c l n l i o n s i n s U ' n d <>!
D i d e r a i l i;il I q u n t i o n s
PUM'fAi
i
Turbulence is considered asF R A C T A L object in
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art £xaroj>£e */ a. Fr^ctat Oijeti
"Hotf Con« is ihe coast 0/
t (13a)
//
A :
QS
one-dim. measute is <*>> TAe coosidne i«kes on inietmeJiate
posUion Between ocutve on a
10
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ihe measure ««comes
Themonw
fine stiuctutescaEeS
a math, exampfe. -*J>e von, /<oc/l>
oo )
B
=:> a hon- TtcitftoCPc continuous
ihe SeC^-simifa^ fi
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Hov/ to iake into account thece o/ i-7e /tne-scafe
y SpatiaB ScaPeS ?
moQo^oV (135*):
/ / (A) = tfic cove^ina numiez =ifce mtrv
A h€e<Jed to co\/ez iAeSet
The von, /<ocfi cutve
(X) =
A -0 -
in
The Canton set %
N D =
"dust"12
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Jistxitt/kion, of ike «ne<t$J4- the moqnefi'c -fietJ -(EuetuorkionS
ifiri
0
0 0 v„
<?
13
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Oi petcoEcktinQ network of /IWs
t
14
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Fox. FRACTAL Distinction of
>
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Le \A <j t d
L
%l
pRODUCFFRACTAL OBJECT
VJ
F.
V
16
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FRACTAL PARAMETERS
IN SPATIAL AND TEMPORAL DOMAINS
Relation of 5 - fractal dimension of time seriesand I) - spatial fractal dimension
N
k=\
B(tk+T)-B{th
\
V JWe assume that the fractal aggregate convects
with the constant velocity VR
N
D-2
.D-2k
.D-2
I) - 2 - 1 - 5D + 8 = 3
O = 1, D = 2 —> Euclidean (nonfractal) case
Power low index of Fourier spectraa = 5 - 25 -> 2D - 1
Berry SteadyEquation convection
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The Index of ConntttiifituGeodesic &n£_fl& a Ftactaf ol/ecr: w^
p *th -• connecieJ jiomoyneous
B
«5'<0> d r < 1 discormeciej cludetL^^HlJ|#TVj«nL<»,
A B
Ji"scohnecic3
18
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GLOSSARY of TERMS:
• "CLUMPY" turbulence (not space filling)
• Hausdorff Fractal Dimension - D(generalization of the topological dimension E = 1. 2. 3)
Anomalous ion diffusivity: <8% > =
a = 1 (Einstein diff.) - > a = 2 / ( 2 + g )
subdiffusion ! 0.8
connectivity: "normal" diffusionsuperdiffusion
• Percolat ion Threshold (Alexander - Orbach Conjecture)
• O - Fractal dimension of time series
curve
D + 6 = 3 for convection of turbulence with flow(Milovanov,, Zelenyi, 1993)
S(/) ~ f'a power low index
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INTERBALL-TAIL MIF-M experiment
200 300 400 500seconds, 13:55 UT, 22 December, 1996
600 700
10
10 10 10t, seconds
10
Number of intervals with negative B vs length
x > 5 sec: 75% of points
8 10 12x, seconds
14 16 18 20
20
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Interball-Tail magnetic field, current sheet 16/12/1998
1.4 1.45 1.5 1.55 1.6 1.65 1.7 1.75 r - 1.8
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-organise J steady state ofcuvteift and cici/ePoped magnetic
' 4
>&*&&h*&$^^
tnQ o{ -ihe cu«erit dysfem
iniht cu%ttrit ihtet: Sj£o?e component of ihe ftetd : < I M
CJ
i
"krioiieJ u/eS-ft/re petcoPatinQ netu/otk
"puPBeJ" on iKe
22
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'/'he tote of -the, finite IOA/ Latmatd
ttea Latmoz Radius (i.e.,
cwcvatute radius of -the ion,ntPy ccnticPs, -the
el ~kh@, mQjne^icn -the- cutxertf. <heei: : Q,
ct*
tonf>Qi±ir.t€$ on the,
Einste/a
4 4
tfmcL
23
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A n nuil outs particle diffusion onFsRAC'TAL obi eel.
(() 'Shagnessey Procaccia, 1995. Diffusion on Fractal Objects.)
Diffusion depends on microscopic time scale
of particle random motion ° y
1/ 1/ "Characteristic time
eff -± rjy T ' i, Hkv i ivc latlnis ol ciirvalmc ol particle trajectories
(7 — 0 Dependence on microscopic time disappears
-2Dt ( lassicai I-insicin Diffusion
>. 0 1 < or < 0
s L.--.J
Aniipcrsislcnl Diffusion Persistent Diffusion
Introduction to the problem:D. ben-Avraham, S. Havlin "Diffusion and Reactions in Fractals... "
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Rstimalcs of Anomalous Diffusion andH fleet ive Conductivity.
ff
D
e
mic •>
V
a
9-
a
a•*^ —V
2
2+O-
A t -•>
rL
V
( <J = 0, D-Vrj - classical strong (BOHM) diffusion limit)
Effective conductivity(scattering on magnetic clumps)
ne2r
mi
a
D
25
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Scaling Properties of MaxwellEquations.
4TFVxSBz=—Sj
c
mt
• Current fluctuations <->
the finite ion Larmor radius effects ^ a
• Estimate of cross-tail current.
Effective OHM's law due to scattering on fractal clumps
Differentiation on Fractal field: Vx -> % 2+a
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Self- Consistency Relation.
From the scaling ofMaxwell Equations:
a
From the Definition ofFractal Dimension D
8B\ D-2
• I) — 2 ™ O/(\+CT) Self-ConsistencyCondition
<r~ () , I) = 2 - homogeneous '"clnssical"turbulence
cr> 0, D < 2 Turbulence is
'ML
(J I Ti*ajcctory between magneticobstacles becomes more "wiggled"(current is getting more branched).
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The Alexander-Orbach conjecture
Current Network is at THRESHOLD ofPERCOLATION
r> ~ <J (AO, 1982)
Condition that network is "minimal", but already sufficient
to maintain the global cross-tail current structure.
CRITICALITY CONDITION ^> SOC
Originally checked numerically for many studies (AO, 1982)
analytically (Milovanov, 1997)
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Fractal parameters and Fourier spectra
in the interval of kinetic self-consistency
D — ?
2D
2 + cr
a1 + cr
43
<2
5
(Scaling EM EQs)
(AO conjecture)
l
u - velocity of plasma convection(decelerated SW speed in magnetotail)
[x] => [fl ~
P(f) -
£ = 5-25 =
D + 8
- fa
> 2 D -
Be^ty plasmaEquation convection
u r u
g a
uTWO KINKS in spectra: / * = —
l
73u
a
3
=> 7/3
Universalpower lawspectrum
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Fourier spectrum of multiscale structured"turbulence"
LnP(f)
Nai t - 1
N
w
Q 0.001
rs|3=-3.92
=-1.34 s|2=-2.21A fc • * . . « <
o.oio o.ioof[Hz]
Interball-Tail observations (18.11.96)The [Bz(Z=0)]2
ffl spectrum
l.OC
I. r - Flicker noise. Explicit time dependence of structures.
II. Interval of self-consistency:oxkV, a'
III. X < a ~ smoothness interval: / > « 2 , a =At small scales turbulence becomes space filling
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PROPERTIES of "TURBULENCE"at "Kinetic" scales (>Pi)
Why MHD - approach breaksat certain scale lengths?
MHD interpretation of turbulence:
OCy ~ OCB ~ 5/3 _fluid-like turbulence with frozen in B
non - MHD kinetic model (fractal field)
DB -> (5/3) -> otB = 2DB - 1 =
Dv = 3 - D B = 4/3
a v = 2DV - 1 =
Field fluctuations are decoupledfrom flow fluctuations
BOROVSKX 1997 Magnetotail
as Laboratory for turbulence
Interval 7: March 9,1979: Mttd Activity[x | Flow Velocities i
12-sec resolution)|_ 150g 100
J2 50E 0* . -50^ -100 i
-2000 20 40 60 SO 100 120
8 ___ t Jmin^JTT 7E . ^ ' ' ^ P o w t r Spectral Densities
S1 io'|
Bx , By , Bz
II 104|
c« 2 !10 f
OJ
f [mini
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Interval of Kinetic selfcon'sistency for low-frequency
"turbulence" in the high (3 plasma.
particle dynamics Maxwell law
>X> a ~pi 5 B -> 5U -> 5J_L
s.c/
'CLUMPY" properties of 8 B in Self-consist regime
D ~ 5/3 < 2
. . . Universal JFojyijer_j^ct^aS (/) ~ f~a of fluctuations in
the (5B -* 5U -> 8ji) interval q B = 7 / 3 , a v = 5/3
• n o n - M H D characteristics
. . "Universal" interval10"2 + lO^Hz < / <
Weakness of theory ->Rescaling of Spatial scales to Temporal
KINKS of power-law spectra at both ends of
the "Universal" interval.
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Substorm ONSET as Structural Instability of
percolating current network
Scenario:
• Accumulation of MAGN. ENERGY in tail5 WFT, <JY>t
• 2D highly-branched current system at the THRESHOLD
of CRITIC ALITY could not support the growing <JY>
• OVERCRITICAL CONDITIONS:
Simplification of current network:
• Reduced branching, straightening of current filaments:
Dt, at, D+^? G+i
Cascade of energy to smaller / > larger SCALES
• Reduction of ELASTICITY of current network
~ o+i , due to decrease of BRANCHING
• Structural instability of floating current LOOPS. ~ ??
Current WEDGE?
Rapid 3-dimensionalization of cross-tail current
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1A
enei«/»ons
8 pi•
Earthward
Figure 10. A schematic diagram of the tail current disruptionillustrating the chaotic features of magnetic Held and electriccurrent perturbations in the onset region. The basic concept wasadopted from Ltd et al. [1988, Figure 4].
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Self-consistent fractal description:
"Physical" properties of the turbulence are analyzed by
means of "unconventional" geometric parameters.
GLOSSARY of TERMS
• D = Hausdorff fractal 1 dimension describing spatialdistribution of magnetic turbulence "clumps" accross the
current sheet plane 1 < D < j , ;
(D < 2 — not "space-filling" turbulence).
• <T = connectivity of the fractal set composed of the
magnetic "clumps" 0 < (T < 1.
• I ) = Hausdorff fractal dimension of the current density
percolating network 1 < D < 2.
# JJ . = connectivity of the network 0 < <J < 1
SELF-CONSISTENT REGIME:magnetic field and current density fractal structures aremutually "conjugated"
(D, a) <-> (D+, a+)"duality" property
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a
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PRE-ONSET EVOLUTIONSimplification of the current system: 8WFt
GROWTHPHASE
Reduced branching of current: (jy)t(straightening of current filaments)
Graining of magnetic structure becomes more coarse:(Cascade of energy to large scales from small scales)
D->0
Weakly knotted current systembecomes TOPOLOGICALLY UNSTABLE
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Normalized Wavelet Analysis 85/15-2 (Pa=1, 0=1» K*10;, M«12)—-*•?—
A>
CO
15: o « - t »<
• * -»*£• -» *- >M
' . " • ' • ' • •: " ' . ' . . • • ' ''••.•"'.''' : - : " ^ - ? - . : ? - ; ' . ' • ' • • : ' , * • • " * • ' ' ' • ' : • ' • • : • • : • -
1.2
0.3
°-4
- 0,6
- 0.4
- 0 2
- 0.0
1023:12 23:13 23:15 23:16
Plate 2. Wavelet transform for magnetic field fluctuations ob-served in a current disruption event. Several components of thesignal can be seen, including a signal suggesting waves at highfrequency cascading to lower frequency as" time "progresses.
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CONCLUSIONS-!
1. Structural stability of the stretched magnetotail could beprovided by self-organized turbulence preventing thecoalescence of current filaments.
2. Turbulence is not "space-filling" and self-consistentlysupports multiscale current network "pulled" on themagnetic field "clumps".
3. Turbulence structures could be described within"geometric" approach involving such topologicalparameters as Hausdorff fractal dimension & index ofconnectivity.
4. Self-consistent currents and fields topologies aremutually "conjugated" (dual to each other).
5. At "basic" steady state with minimum of free energy thesystem saturates at the threshold of percolation.
6. In the course of free energy accumulation in the tail(late growth phase) current system overcomes themarginal percolation threshold, and 3D currentfilaments start- to "emerge" from the current sheet dueto simplification of the current network.
7. Evolution of the current network above the percolationthreshold has catastrophic character and resembles thesecond-order phase transition. Current system becomesessentially 3D and has features often associated with theSubstorm Current Wedge.
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MAGNETIC TURBULENCE
AND ION DYNAMICS IN THE
DISTANT MAGNETOTAIL
© 1. Modelling of the Ion Dynamics ID sheet 3D-turbulence6.fi. /99£, (03,
3. 6. ft. 2oo i c #*
2. Multiscale structure.
Attempts of Self-Consistent Description3. 6 .g . W 6 , /££ , v 9 , p.5 - 6 . « 200i , /Of ,
Lev ZELENYI Pierluigi VELTRI
Sandro TAKTAKISHVILI Gaetano ZIMBARDO
Alexander MILOVANOV
Space Research Institute University of Calabria
Moscow Arcavacata di Rende
RUSSIA ITALY
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Pie I 4
X - - • • - • • •
5SSO•••'•*•/' -"—*"-"« t--
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Magnetic Field Model
Modified Harris profile with fluctuations:
B = B ,lc~a
_2
Box(z) = B0t a n h ( z / X)- ( z / X) c o s h " 2 (L I2X)
t a n h ( Z / 2 X ) - ( L I 2 X ) c o s h " 2 ( L / 2 X )
for |zj| = L /2 oBox^zj/oz^O
X - sheet half thickness, L- scale of the simulation box
1
1). 2-polarizat ions foreach mode :
c r = l
a 14 + 1 / 2
1) Parity conditions
(x, y, z) = -<BXJ,(x, y-z)
3). Correlation lengths:4). Harris sheet half thickness5) Simulation box
lx=ly=0.25L lz=0.05L
periodicconditions
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•1 I
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-1.0-
-0.4 -0.2
a) Y-.O
X
0.0z/L
0.2
b) 0
0.4
11 -it'-ll'-
< \ \
v 1
i l l\\\ \
t 1
0.8-1
0.6
0.4-
0.2-
0.0
I\
\ \I i 'i t .i i •
t i
! iI ;/ /
i i / ' * \ \ 'i i i i i t i '
i ii ii i
XN?\ V — • - -
M\11I I\\
- M -
d)
\ \\ \ \\
I i\ \\ -
i I
! I iII
I 'I lI I
I 1mm
i i
-o.i -0.05 0.0
z/L0.05 -0.1 -0.05 0.0 0.05 0.1
Wos
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1.0
X
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B,
-10
1200-1
1000-
r FETIMESUSTEM:
0
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o zrr0 Us
v o
v
o
p -I
pto
Temperature, TzH^ K) U> 4^ Lho o o o oo o o o oo o o o o
Current density, j
H
IXooas
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PRESSURE BALANCE AND ENERGY BUDGET
pzz + VZ « const — « 0.3
contrary to Bn «const case contibution of stresses due to off-diagonal terms is negligible
y=20LQv +
enthalpy W=U+Pyy
y.
heat flux<5%, Enthalpy~90%, directed energy-5-8%
heating is almost isotropic T|| ^ 1^
Proper sharing of energy between heating and currentmaintainance is achieved
only for
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0.25^
0.2-
^0.15
II o.H
0.05 H
0.0
<n>t w»1 Bo
-0.4 -0.2 0.0 0.2
z/L0.4
1000
£ 800
a
o 60000C/3
134 >
400 H
H 200 H
0
-0.4 -0.2 0,0 0.2
z/L0.4
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current density, jyo
o _
Oo
O
O
temperatiue, T
density, nooio
oo
o
,c»
o
(I/I
V \
o b
<
s i ^ ^ ' ^;
\J
/
t'
\i
i.
bulk velocity, Vy
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CONCLUSIONS - jl
The thickness of the current sheet rapidlygrows with the increase of the level offluctuations 5B/B0.
For 8B/Bo~0.3 enough scattering is producedby 8B to inflate the current sheet. Particlecurrent ~ corresponds to the Box(z).
For SB/Bo>0.3 double humped currentstructure is formed (in accordance with Geotailmeasurments).
Temperature variation across current sheet isvery essential P(z)=n(z) T(z).
For 5B/Bo>0.2 main part (90%) of electricenergy is converged to the randomization ofion distribution and quasi isotropic heating upto 5-10 keV. Only 5% - 8% of potential dropgoes to acceleration and current maintainance.
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REFERENCES for LECTURE 3
A. Results of Lecture 3 are published in following papers:
1. Milovanov A.V., L.M.Zelenyi. Applications of Fractal Geometry to Dynamicalevolution of Sunspots. Phys. Fluids, B, 5, 7, 2609-2615, 1993.
2. Milovanov A., L.Zelenyi, G.Zimbardo. Fractal Structures and Power-Law Spectra in theDistant Earth's Magnetotail. J.Geophys.Res., 101, A9,19903-19910, 1996.
3. Zelenyi L.M., A.V.Milovanov, G.Zimbardo. Multiscale magnetic structure of thedistant-tail: self-consistent fractal Approach. AGU, Geophys.Monograph 105, 321-339,1998.
4. Veltri P., G.Zimbardo, A.L.Taktakishvili, L.M.Zelenyi. Effect of magnetic turbulenceon the ion dynamics in the distant magnetotail. J. Geophys.Res., 103, A7, 14897-14910,1998.
5. Milovanov A.V., L.M.Zelenyi Functional background of the Tsallis entropy: "coarse-grained" systems and "kappa" distribution functions. J. Nonlinear Processes inGeophysics, 7, 3/4, 211-221, 2000.
6. Milovanov A. V., L.M.Zelenyi, P. Veltri, G.Zimbardo. Self-organized branching ofmagnetotail current systems near the percolation threshold. J.Geophys.Res., 106, A-4,6291-6307,2001
7. Milovanov A.V., L.M.Zelenyi, P.Veltri, G.Zimbardo, A.L.Taktakishvili. Geometricdescription of the magnetic field and plasma coupling in the near-Earth stretched tail priorto a substorm. Atmospheric& Solar-Terrestrial Phys., 63, 5, 705-721, 2001.
8. Greco A., A.L.Taktakishvili, G.Zimbardo, P.Veltri, L.M.Zelenyi. Ion dynamics in thenear Earth magnetotail: magnetic turbulence versus normal component of the averagemagnetic field. J. Geophys. Res. 2001. (in press)
9. Milovanov A. V., L.M.Zelenyi. "Strange" Fermi processes and power-law nonthermaltails from a self-consistent fractional kinetic equation. Phys. Rev. E, 64, 2001. (in press)
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B. Additional important publications:
1. Alfven H. Some properties of magnetospheric neutral surfaces. L. Geophys. Res., 73,4379, 1968.
2. Burlaga L.F., L.W.Klein. Fractal structure of the interplanetary magnetic field. J.Geophys. Res., 91, A1, 347-350, 1986
3. Ambrosiano J., W.H.Matthaeus et al. Test particle acceleration in turbulentreconnecting magnetic fields. J. Geophys. Res., 93, 14383, 1988.
4. Hoshino M., A.Nishida, et al. Turbulent magnetic field in the distant tail: Bottom-upprocess of plasmoid formation? Geophys. Res. Lett., 21, 2935, 1994.
5. Nishida A., T.Yamamoto et al. Structure of the neutral sheet in the distant tail (x ̂210 RR) in geomagnetically quiet times. Geophys. Res. Lett., 21, 2951, 1994.
6. Bauer T.M., W.Baumjohann, et al. Low-frequency waves in the near-Earth plasmasheet. J. Geophys. Res., 100, 9605, 1995.
7. Ohtani S., T.Higuchi et al. Magnetic fluctuations associated with tail current disruption:Fractal analysis. J. Geophys. Res., 100, 19, 135, 1995.
8. Borovsky J.E., R.C.Elphic et al. The Earth's plasma sheets as a laboratory for flowturbulence in high-p MHD. J. Plasma Phys., 57, 1, 1997.
9. Lui A.T.Y., A.-H.Najmi. Time frequency decomposition of signals in a currentdisruption event. Geophys. Res. Lett., 24, 3157, 1997.
10. Consolini G., A.T.Y.Lui. Sign-singularity analysis of a current disruption event.Geophys. Res. Lett., 26, 1673, 1999.
11. Alexander S., R.L.Orbach. Density of states on fractals. J.Phys.Lett., 43, L625. 1982.
12. Berry M.V. Diffractals. J. Phys. A Math. Gen., 12, 781, 1979.
13. Gefen Y., A.Aharony, S.Alexander. Anomalous diffusion on percolating clusters.Phys. Rev. Lett., 50, 77, 1983.
14. O'Shaughnessy B., I.Procacccia. Diffusion on fractals. Phys. Rev. A, 3073, 1985.
15. Milovanov A.V. Topological proof for the Alexander-Orbach conjecture. Phys. Rev.E, 56, 2437, 1997.
16. Biichner J., Kuska J.-P. Sausage mode instability of thin current sheets as a cause ofmagnetospheric substorms. Ann. Geophysicae, 17, 604, 1999.
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17. Biichner J., Kuska J.-P. Numerical simulation of three-dimensional reconnection due tothe instability of collisionless current sheets. Adv. Space Res., 19, 1817, 1997.
18. Wegelmann T., J. Biichner. Kinetic simulations of the coupling between currentinstabilities and reconnection in thin current sheets. Nonlinear Proc. In Geoph., 7, 141,2000.
C. TEXTBOOKS
J. Feder J. Fractals, Plenum, New York, 1988.
2. Ben-Avraham D., S.Havlin. Diffusion and reactions in fractals and Disordered systems.Cambridge University Press, 2000.
3. Isichenko M.B. Percolation statistical topography, and transport in random media. Rev.Mod. Phys., 64, 961, 1992.
4. Stauffer D., A.Aharony. Introduction percolation theory. Taylor & Francis, 1998.
5. Mandelbrot B.B. The Fractal Geometry of Nature. W.H.Freeman, New York, 1983.
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