P41

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Transcript P41 

Simulation Study of Three-Dimensional and Nonlinear
Dynamics of Flux Rope in the Solar Corona
INOUE Satoshi(Hiroshima University/Earth Simulator Center), KUSANO Kanya(Earth Simulator Center)
E-mail : [email protected]
Abstract
We numerically investigated the three-dimensional(3D) stability and the nonlinear dynamics of flux rope embedded in magnetic
arcade. As a results, we found that the flux rope is unstable to the kink mode instability, as the system approach to the lossof-equilibrium state. The 3D simulation shows that when the flux rope is long enough, it can escape from the arcade with almost
constant speed after the accelerated launching due to the kink instability. This constant ascending is driven by magnetic
reconnection on the current sheet, which is formed above the magnetic neutral line as a consequence of the instability. However,
when the flux rope is short enough , the current sheet can not be maintained, so that the ascending is failed at some height.
These results imply that the nonlinear effect mainly influenced by magnetic reconnection may determine whether the flux rope is
ejected or not.
2Dsimulation
Lx=0.6
Priest , Forbes(1990) proposed Loss-of-equilibrium model to
explain filament eruption phenomena. This model is that the
changing boundary condition causes filament eruption due to
brake the equilibrium condition. Because filament is stability in
two-dimensional space, it was able to arrive at loss-of-equilibrium
point, so this model was not considered three-dimensional insta
-bility. Therefore, we investigated the stability around loss-ofequilibrium point in three-dimensional space.
Loss of Equilibrium point
Lx=1.5
h
d
m
( M )
Iod
Fig1(a)
Fig2(a)
Fig1(a) is equilibrium line for Flux Rope embedded in coronal loop.
Fig2(b) is the flux rope dynamics in two-dimensional space as M=1.5.
Linear Stability Analysis
The equilibriums from Priest, Forbes become unstable to kink
mode instability. The equilibriums near the loss of equilibrium
are more unstable than other equilibriums. Therefore it is possible that filament eruption is occurred due to instability before
reach the loss-of-equilibrium point.
γ
h
d
h
d
m
( M )
Iod
Loss of Equilibrium Point
Fig2(a)
Fig2(b)
Fig2(c)
Fig2(a) is equilibrium line for Flux Rope embedded in coronal loop.
Fig2(b) is represented the linear growth rate vs. h/d.
Fig2(c) is eigen-functions.
Parameters,
m : Dipole moment, d : Dipole depth from solar surface
h : Filament height from solar surface I0 : Current in Flux Tube
Fig3(a)
the flux rope, and the red surface is an isosurface of the current intensity
|J|. We can see that firstly the center of the flux rope is lifted up due to
the growth of kink mode, and secondary the field lines evolve nonlinearly.
Fig(b) is the time profile of height and velocity of flux tube in the both
cases. We showed that the ascending of short flux tube(Lx=0.6) is failed
at certain height, whereas the long flux tube continuously ascends after
the growth of the kink mode instability. In the final state of Fig(a), the
current sheet is sustained in long flux tube, although it disappears in short
one. It may be important the current sheet formation in the late phase that
the filament continuously ascends.
Discussion
We carried out a hypothetical simulation to confirm the importance of
current sheet formation, i.e, magnetic reconnection on it. In the case of
failed eruption(Lx=0.6, M=2.0875), we imposed an external force on the
center of the flux rope from t=22.49 to 27.63. By this force, the stretching
of the field line corresponding to feet of the arcade may further help the
formation of current sheet, so that reconnection could be self-sustained.
As a result, flux tube is enlarged and, by external force, forms current
sheet in the lower part. Furthermore, the flux tube ascending because
reconnection is self-sustained in the lower part after finishing external
force without failing. Fig4(a) is represented the 3D flux rope structure
acted external force, Fig4(b) is the current sheet distributions, Fig4(c)
is time profile of flux rope height, red line is no external force, and blue
line is acted external force.
3Dsimulation
We show the results of the 3D MHD simulation. The different equilibria
for M=2 and M=2.08 were used as the initial conditions, respectively.
The Two simulations were carried out respectively for Lx=0.6 and 1.5
, in which the system length Lx=0.6 corresponds to the wave length
giving the maximum growth rate. The eigen-functions obtained from the
linear growth calculation are added to the equilibrium as small and initial
perturbation. We represented the flux tube dynamics in the three-dimen
-sional space. The upper panel is case for Lx = 0.6, the lower panel is for
Lx = 1.5 at M=2. In these figures, each string represents magnetic field
line, green surface is an isosurface of the strength Bx, which is along
Fig3(b)
Fig4(a)
Summary
Fig4(c)
Fig4(b)
(1) It is important the formation of current sheet in the lower part that
flux rope continuously ascends without failing at certain height.
(2) There could be a critical height beyond which filament must exceed
to escape to the infinity.