4,270 research outputs found
More on the determination of the coronal heating function from Yohkoh data
Two recent works have analyzed a solar large and steady coronal loop observed
with Yohkoh/SXT in two filter passbands to infer the distribution of the
heating along it. Priest et al. (2000) modelled the distribution of the
temperature obtained from filter ratio method with an analytical approach, and
concluded that the heating was uniform along the loop. Aschwanden (2001) found
that a uniform heating led to an unreasonably large plasma column depth along
the line of sight, and, using a two component loop model, that a
footpoint-heated model loop (with a minor cool component) yields more
acceptable physical solutions. We revisit the analysis of the same loop system,
considering conventional hydrostatic single loop models with uniformly
distributed heating, and with heating localized at the footpoints and at the
apex, and an unstructured background contribution extrapolated from the region
below the analyzed loop. The flux profiles synthesized from the loop models
have been compared in detail with those observed in both filter passbands with
and without background subtraction; we find that background-subtracted data are
fitted with acceptable statistical significance by a model of relatively hot
loop (~3.7 MK) heated at the apex, with a column depth ~1/10 of the loop
length. In discussing our results, we put warnings on the importance of aspects
of data analysis and modeling, such as considering diffuse background emission
in complex loop regions.Comment: 17 pages, 4 figures, refereed pape
Prominence plasma diagnostics through EUV absorption
In this paper we introduce a new diagnostic technique that uses prominence
EUV and UV absorption to determine the prominence plasma electron temperature
and column emission measure, as well as He/H relative abundance; if a realistic
assumption on the geometry of the absorbing plasma can be made, this technique
can also yield the absorbing plasma electron density. This technique
capitalizes on the absorption properties of Hydrogen and Helium at different
wavelength ranges and temperature regimes. Several cases where this technique
can be successfully applied are described. This technique works best when
prominence plasmas are hotter than 15,000 K and thus it is ideally suited for
rapidly heating erupting prominences observed during the initial phases of
coronal mass ejections. An example is made using simulated intensities of 4
channels of the SDO/AIA instrument. This technique can be easily applied to
existing observations from almost all space missions devoted to the study of
the solar atmosphere, which we list.Comment: 17 pages, 4 figures, submitted to Ap
TRACE-derived temperature and emission measure profiles along long-lived coronal loops: the role of filamentation
In a recent letter (ApJ 517, L155) Lenz et al. have shown the evidence of
uniform temperature along steady long coronal loops observed by TRACE in two
different passbands (171 A and 195 A filters). We propose that such an evidence
can be explained by the sub-arcsecond structuring of the loops across the
magnetic field lines. In this perspective, we present a model of a bundle of
six thin parallel hydrostatic filaments with temperature stratification
dictated by detailed energy balance and with temperatures at their apex ranging
between 0.8 and 5 MK. If analyzed as a single loop, the bundle would appear
isothermal along most of its length.Comment: 9 pages, 4 figs, LaTeX text, PostScript figure
Magnetic shuffling of coronal downdrafts
Channelled fragmented downflows are ubiquitous in magnetized atmospheres, and
have been recently addressed from an observation after a solar eruption. We
study the possible back-effect of the magnetic field on the propagation of
confined flows. We compare two 3D MHD simulations of dense supersonic plasma
blobs downfalling along a coronal magnetic flux tube. In one, the blobs move
strictly along the field lines; in the other, the initial velocity of the blobs
is not perfectly aligned to the magnetic field and the field is weaker. The
aligned blobs remain compact while flowing along the tube, with the generated
shocks. The misaligned blobs are disrupted and merged by the chaotic shuffling
of the field lines, and structured into thinner filaments; Alfven wave fronts
are generated together with shocks ahead of the dense moving front. Downflowing
plasma fragments can be chaotically and efficiently mixed if their motion is
misaligned to field lines, with broad implications, e.g., disk accretion in
protostars, coronal eruptions and rain.Comment: 9 pages, 4 figures, proposed for acceptance, movies available upon
request to the first autho
Guided flows in coronal magnetic flux tubes
There is evidence for coronal plasma flows to break down into fragments and
to be laminar. We investigate this effect by modeling flows confined along
magnetic channels. We consider a full MHD model of a solar atmosphere box with
a dipole magnetic field. We compare the propagation of a cylindrical flow
perfectly aligned to the field to that of another one with a slight
misalignment. We assume a flow speed of 200 km/s, and an ambient magnetic field
of 30 G. We find that while the aligned flow maintains its cylindrical symmetry
while it travels along the magnetic tube, the misaligned one is rapidly
squashed on one side, becoming laminar and eventually fragmented because of the
interaction and backreaction of the magnetic field. This model could explain an
observation of erupted fragments that fall back as thin and elongated strands
and end up onto the solar surface in a hedge-like configuration, made by the
Atmospheric Imaging Assembly on board the Solar Dynamics Observatory. The
initial alignment of plasma flow plays an important role in determining the
possible laminar structure and fragmentation of flows while they travel along
magnetic channels.Comment: 11 pages, 8 figures, accepted for publication, movies available upon
request to the first autho
Non-equilibrium of Ionization and the Detection of Hot Plasma in Nanoflare-heated Coronal Loops
Impulsive nanoflares are expected to transiently heat the plasma confined in
coronal loops to temperatures of the order of 10 MK. Such hot plasma is hardly
detected in quiet and active regions, outside flares. During rapid and short
heat pulses in rarified loops the plasma can be highly out of equilibrium of
ionization. Here we investigate the effects of the non-equilibrium of
ionization (NEI) on the detection of hot plasma in coronal loops.
Time-dependent loop hydrodynamic simulations are specifically devoted to this
task, including saturated thermal conduction, and coupled to the detailed
solution of the equations of ionization rate for several abundant elements. In
our simulations, initially cool and rarified magnetic flux tubes are heated to
10 MK by nanoflares deposited either at the footpoints or at the loop apex. We
test for different pulse durations, and find that, due to NEI effects, the loop
plasma may never be detected at temperatures above ~5 MK for heat pulses
shorter than about 1 min. We discuss some implications in the framework of
multi-stranded nanoflare-heated coronal loops.Comment: 22 pages, 7 figures, accepted for publicatio
Hydrodynamic modelling of ejecta shrapnel in the Vela supernova remnant
Many supernova remnants (SNRs) are characterized by a knotty ejecta
structure. The Vela SNR is an excellent example of remnant in which detached
clumps of ejecta are visible as X-ray emitting bullets that have been observed
and studied in great detail. We aim at modelling the evolution of ejecta
shrapnel in the Vela SNR, investigating the role of their initial parameters
(position and density) and addressing the effects of thermal conduction and
radiative losses. We performed a set of 2-D hydrodynamic simulations describing
the evolution of a density inhomogeneity in the ejecta profile. We explored
different initial setups. We found that the final position of the shrapnel is
very sensitive to its initial position within the ejecta, while the dependence
on the initial density contrast is weaker. Our model also shows that moderately
overdense knots can reproduce the detached features observed in the Vela SNR.
Efficient thermal conduction produces detectable effects by determining an
efficient mixing of the ejecta knot with the surrounding medium and shaping a
characteristic elongated morphology in the clump.Comment: Accepted for publication in Monthly Notices of the Royal Astronomical
Societ
Mass Accretion Processes in Young Stellar Objects: Role of Intense Flaring Activity
According to the magnetospheric accretion scenario, young low-mass stars are
surrounded by circumstellar disks which they interact with through accretion of
mass. The accretion builds up the star to its final mass and is also believed
to power the mass outflows, which may in turn have a significant role in
removing the excess angular momentum from the star-disk system. Although the
process of mass accretion is a critical aspect of star formation, some of its
mechanisms are still to be fully understood. On the other hand, strong flaring
activity is a common feature of young stellar objects (YSOs). In the Sun, such
events give rise to perturbations of the interplanetary medium. Similar but
more energetic phenomena occur in YSOs and may influence the circumstellar
environment. In fact, a recent study has shown that an intense flaring activity
close to the disk may strongly perturb the stability of circumstellar disks,
thus inducing mass accretion episodes (Orlando et al. 2011). Here we review the
main results obtained in the field and the future perspectives.Comment: 4 pages, 2 Figures; accepted for publication on Acta Polytechnica
(Proceedings of the Frascati Workshop 2013
Magnetohydrodynamic Turbulent Cascade of Coronal Loop Magnetic Fields
The Parker model for coronal heating is investigated through a high
resolution simulation. An inertial range is resolved where fluctuating magnetic
energy E_M (k_perp) \propto k_\perp^{-2.7} exceeds kinetic energy E_K (k_\perp)
\propto k_\perp^{-0.6}. Increments scale as \delta b_\ell \simeq \ell^{-0.85}
and \delta u_\ell \simeq \ell^{+0.2} with velocity increasing at small scales,
indicating that magnetic reconnection plays a prime role in this turbulent
system. We show that spectral energy transport is akin to standard
magnetohydrodynamic (MHD) turbulence even for a system of reconnecting current
sheets sustained by the boundary. In this new MHD turbulent cascade, kinetic
energy flows are negligible while cross-field flows are enhanced, and through a
series of "reflections" between the two fields, cascade more than half of the
total spectral energy flow.Comment: 5 pages, 5 figures, to appear in Physical Review E - Rapid. Com
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