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![Page 1: Kinetic Alfvén turbulence driven by MHD turbulent cascade Yuriy Voitenko & Space Physics team Belgian Institute for Space Aeronomy, Brussels, Belgium Multifractal.](https://reader036.fdocuments.in/reader036/viewer/2022062500/5697bfa31a28abf838c9678c/html5/thumbnails/1.jpg)
Kinetic Alfvén turbulence driven byMHD turbulent cascade
Yuriy Voitenko & Space Physics teamBelgian Institute for Space Aeronomy, Brussels, Belgium
Multifractal and turbulence workshop - 2010 (8-11 June 2009, Space Pole, Belgium)
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Aurora – multifractal? (photo by Jan Curtic)
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Outline
Kinetic Alfvén waves (KAWs) are the extensions of their MHD counterparts in the range of short (kinetic) cross-field wavelengths comparable to ion gyroradius or electron inertial length (Hasegawa and Chen, 1975 ).
Contrary to MHD Alfvén waves, KAWs are efficient in the field-aligned acceleration of electrons and ions and cross-field acceleration of ions.
What to see:
the alfvenicity determines the transition between MHD and kinetic domains where different cascade mechanisms dominate.
KAWs interact nonlinearly among themselves and form power-law turbulent spectra (Voitenko, 1998a,b).
KAWs interact with plasma and deposit energy in plasma species.
Spectral distributions of the KAW energy provides the possibility of a spectrally localised ion heating acceleration.
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At small wave lengths cascading AWs meet natural length scales reflecting plasma microstructure:
ion gyroradius ion gyroradius ii (reflects gyromotion and ion (reflects gyromotion and ion
pressure effects); pressure effects); ion gyroradius at electron temperature ion gyroradius at electron temperature ss (reflects (reflects
electron pressure effects); electron pressure effects); ion inertial length ion inertial length ii (reflects effects due to ion (reflects effects due to ion
inertia), and inertia), and electron inertial length electron inertial length ee (reflects effects due to (reflects effects due to
electron inertia).electron inertia).
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z
x
Bo
due to ion polarisation drift
Cross-field ion currents
Wave electric field Ex vary with z but not with x
MHD Alfven wave:
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kinetic Alfven wave: short cross-field wavelength
Bo
Cross-field ion currents build up
ion space charges and holes
Field-aligned electron currents try to compensate ion charges
but fail (electron inertia and/or
electron pressure effects) Parallel electric field arise
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decay of a pump KAW into two co-streaming KAWs (1998b)
k zV AK(k 2
)
k zV AK(
k 1)
k zV AK(k P
)
k1z kz
P
P = 1 + 2; kP = k1 + k2
k2z kPz
1
2
Час розпаду [(VA/р)(kPρi)3(Bk/B0)]
-1.
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decay of a pump KAW in two counter-streaming KAWs (1998b)
kz V
AK(k2 )
k zVAK(k 1
)k zV AK(k P
)
k1z kz
P
k2z kPz
1
2
Час розпаду [(VA/р)(kPρi)2(Bk/B0)]
-1.
P = 1 + 2; kP = k1 + k2
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Electron energization by KAWs:effect of parallel electric field
Ez || B0
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Electron heating by KAWs: Landau damping
Vz
VA
VTi Vph1 Vph2
Fi
Fe
KAWs are here
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MHDwaves
Kinetic Alfvénwaves
Super-adiabatic cross-field ion acceleration
Resonant plasma heating and particle acceleration
Demagnetization of ion motion Kinetic wave-particle interaction
Phase mixing
Turbulent cascade
Kinetic instabilities
Parametric decay
UnstablePVDs
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Wygant et al. (2002) – evidence of parallel electron acceleration by KAWs at 4 Earth radii
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Equation for cross-field ion velocity in the presence of KAWs:
In the vicinity of demagnetizing KAW phases
the solution can grow exponentially as
Specify KAW fields as:
where K is the KAW phase velocity (dispersion). In the two-fluid model
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0.5A
n-a/p
(mi/qi)/(mp/qp) A-1 2A-1
A = kxp K(kx)1 + kx
2p2
________B0
B___
O+H+ He+
1 2 16
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Some important properties of the super-adiabatic ion acceleration by KAWs:
•Non-resonant, frequency independent•Bulk kick-like acceleration across the magnetic fieldafter single super-critical KAW fluctuation•Depends on the parallel ion velocity•Threshold-like in wave amplitude and/or cross-field wavelength
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Perpendicular velocity of an ion in a super-critical KAW wave train
Phase portrait of the ion’s orbit in the region of super-adiabatic acceleration (transition of the demagnetizing wave phase 3 pi)
t
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PROTON VELOCITY DISTRIBUTIONS IN THE SOLAR WIND
(HELIOS MEASUREMENTS)
The origin of velocity space relates to
the maximum of the distribution.
Isodensity contours correspond to
fractions of 0.8, 0.6, 0.4, 0.2 and of
0.1, 0.03, 0.01, 0.003, 0.001 (dashed
contours). The vector of solar wind
flow is along VY axis, the vector of
magnetic field is along dash line.
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KAW turbulence (Voitenko, 1998): (i) dual perpendicular cascades;(ii) power law spectra k
-p , 2<p<4; (iii) excitation of the counter-streaming KAWs - imbalanced turbulence, k
-2 (p=2);
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Hamrin et al. (2002) estimated spectral slope of the BBELF turbulence observed by Freja as p=-2,5
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Spectra steepened with higher k: intermittent dissipation range
Approximate condition for non-adiabatic ion acceleration
acceleration occurs around spectral break
Constant Nb depends on the KAW amplitudes at the spectral break
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Condition for non-adiabatic ion acceleration by power-law spectrum:
Let it be satisfied for ions with initial at some , wherethey undergo initial cross-field acceleration.Then magnetic mirror force come into play and accelerate these ions upward along Bo, increasing upward (negative) . Increased , in turn makes more turbulent energy accessible for ions (the condition is satisfied at lower and higher perturbation amplitudes) -> positive feed-back loop
Effect of : surfing acceleration of ions along Bo
spreading of the acceleration
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KAW
k
||
k i -1
i-1
R
-1
_
| |
I o n - c y c l o t r o n
L a n d a u
M A C R O ( M H D )
m i c r o ( k i n e t i c )
N o n a d i a b a t
c i
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• transition MHD->KAW at low k_perp ;• parallel electron/ion heating;• importance of KAW turbulent spectra;• cross-field ion heating by KAW turbulence;
Conclusions