2,198 research outputs found
Probing quiet Sun magnetism using MURaM simulations and Hinode/SP results: support for a local dynamo
We obtain information about the magnetic flux present in the quiet Sun by
comparing radiative MHD simulations with Hinode/SP observations, with
particular emphasis on the role of surface dynamo action. Simulation runs with
different magnetic Reynolds numbers (Rm) are used together with observations at
different heliocentric angles with different levels of noise. The results show
that simulations with an imposed mixed-polarity field and Rm below the
threshold for dynamo action reproduce the observed vertical flux density, but
do not display a sufficiently high horizontal flux density. Surface dynamo
simulations at the highest Rm feasible at the moment yield a ratio of the
horizontal and vertical flux density consistent with observational results, but
the overall amplitudes are too low. Based on the properties of the local dynamo
simulations, a tentative scaling of the magnetic field strength by a factor 2 -
3 reproduces the signal observed in the internetwork regions. We find an
agreement with observations at different heliocentric angles. The mean field
strength in internetwork, implied by our analysis, is roughly 170 G at the
optical depth unity. Our study shows that surface dynamo could be responsible
for most of the magnetic flux in the quiet Sun outside the network given that
the extrapolation to higher Rm is valid.Comment: accepted in A&
Magnetic field intensification: comparison of 3D MHD simulations with Hinode/SP results
Recent spectro-polarimetric observations have provided detailed measurements
of magnetic field, velocity and intensity during events of magnetic field
intensification in the solar photosphere. We consider the temporal evolution of
the relevant physical quantities for three cases of magnetic field
intensification in a numerical simulation. We determine the evolution of the
intensity, magnetic flux density and zero-crossing velocity derived from the
synthetic Stokes parameters by taking into account the spectral and spatial
resolution of the spectropolarimeter (SP) on board Hinode. The three events
considered show a similar evolution: advection of magnetic flux to a granular
vertex, development of a strong downflow, evacuation of the magnetic feature,
increase of the field strength and the appearance of the bright point. We find
that synthetic and real observations are qualitatively consistent and, for one
of the cases considered, agree very well also quantitatively. The effect of
finite resolution (spatial smearing) is most pronounced in the case of small
features, for which the synthetic Hinode/SP observations miss the bright point
formation and also the high-velocity downflows during the formation of the
smaller magnetic features.Comment: accepted in A&
Probing photospheric magnetic fields with new spectral line pairs
The magnetic line ratio (MLR) method has been extensively used in the
measurement of photospheric magnetic field strength. It was devised for the
neutral iron line pair at 5247.1 A and 5250.2 A (5250 A pair). Other line pairs
as well-suited as this pair been have not been reported in the literature. The
aim of the present work is to identify new line pairs useful for the MLR
technique and to test their reliability. We use a three dimensional
magnetohydrodynamic (MHD) simulation representing the quiet Sun atmosphere to
synthesize the Stokes profiles. Then, we apply the MLR technique to the Stokes
V profiles to recover the fields in the MHD cube both, at original resolution
and after degrading with a point spread function. In both these cases, we aim
to empirically represent the field strengths returned by the MLR method in
terms of the field strengths in the MHD cube. We have identified two new line
pairs that are very well adapted to be used for MLR measurements. The first
pair is in the visible, Fe I 6820 A - 6842 A (whose intensity profiles have
earlier been used to measure stellar magnetic fields), and the other is in the
infrared (IR), Fe I 15534 A - 15542 A. The lines in these pairs reproduce the
magnetic fields in the MHD cube rather well, partially better than the original
5250 A pair. The newly identified line pairs complement the old pairs. The
lines in the new IR pair, due to their higher Zeeman sensitivity, are ideal for
the measurement of weak fields. The new visible pair works best above 300 G.
The new IR pair, due to its large Stokes V signal samples more fields in the
MHD cube than the old IR pair at m, even in the presence of noise,
and hence likely also on the real Sun. Owing to their low formation heights
(100-200 km above tau_5000=1), both the new line pairs are well suited for
probing magnetic fields in the lower photosphere.Comment: Accepted for publication in Astronomy & Astrophysic
Fluxtube model atmospheres and Stokes V zero-crossing wavelengths
First results of the inversion of Stokes I and V profiles from plage regions
near disk center are presented. Both low and high spatial resolution spectra of
FeI 6301.5 and FeI 6302.5 A obtained with the Advanced Stokes Polarimeter (ASP)
have been considered for analysis. The thin flux tube approximation,
implemented in an LTE inversion code based on response functions, is used to
describe unresolved magnetic elements. The code allows the simultaneous and
consistent inference of all atmospheric quantities determining the radiative
transfer with the sole assumption of hydrostatic equilibrium. By considering
velocity gradients within the tubes we are able to match the full ASP Stokes
profiles. The magnetic atmospheres derived from the inversion are characterized
by the absence of significant motions in high layers and strong velocity
gradients in deeper layers. These are essential to reproduce the asymmetries of
the observed profiles. Our scenario predicts a shift of the Stokes V
zero-crossing wavelengths which is indeed present in observations made with the
Fourier Transform Spectrometer.Comment: To appear in ApJ Letters (1997) (in press
The dark side of solar photospheric G-band bright points
Bright small-scale magnetic elements found mainly in intergranular lanes at
the solar surface are named bright points (BPs). They show high contrasts in
Fraunhofer G-band observations and are described by nearly vertical slender
flux tubes or sheets. A recent comparison between BP observations in the
ultraviolet (UV) and visible spectral range recorded with the balloon-borne
observatory SUNRISE and state-of-the-art magnetohydrodynamical (MHD)
simulations revealed a kiloGauss magnetic field for 98% of the synthetic BPs.
Here we address the opposite question, namely which fraction of pixels hosting
kiloGauss fields coincides with an enhanced G-band brightness. We carried out
3D radiation MHD simulations for three magnetic activity levels (corresponding
to the quiet Sun, weak and strong plage) and performed a full spectral line
synthesis in the G-band. Only 7% of the kiloGauss pixels in our quiet-Sun
simulation coincide with a brightness lower than the mean quiet-Sun intensity,
while 23% of the pixels in the weak-plage simulation and even 49% in the
strong-plage simulation are associated with a local darkening. Dark
strong-field regions are preferentially found in the cores of larger flux
patches that are rare in the quiet Sun, but more common in plage regions, often
in the vertices of granulation cells. The significant brightness shortfall in
the core of larger flux patches coincide with a slight magnetic field
weakening. KiloGauss elements in the quiet Sun are on average brighter than
similar features in plage regions. Almost all strong-field pixels display a
more or less vertical magnetic field orientation. Hence in the quiet Sun,
G-band BPs correspond almost one-to-one with kiloGauss elements. In weak plage
the correspondence is still very good, but not perfect.Comment: Accepted for publication in Astronomy & Astrophysic
Solar extreme ultraviolet variability of the quiet Sun
The last solar minimum has been unusually quiet compared to the previous
minima (since space-based radiometric measurements are available). The Sun's
magnetic flux was substantially lower during this minimum. Some studies also
show that the total solar irradiance during the minimum after cycle 23 may have
dropped below the values known from the two minima prior to that. For
chromospheric and coronal radiation, the situation is less clear-cut. The Sun's
10.7\,cm flux shows a decrease of during the solar minimum in 2008
compared to the previous minimum, but \ion{Ca}{II} K does not. Here we consider
additional wavelengths in the extreme ultraviolet (EUV), specifically
transitions of \ion{He}{I} at 584.3\,\AA\ and \ion{O}{V} at 629.7\,\AA , of
which the CDS spectrometer aboard SOHO has been taking regular scans along the
solar central meridian since 1996. We analysed this unique dataset to verify if
and how the radiance distribution undergoes measurable variations between cycle
minima. To achieve this aim we determined the radiance distribution of quiet
areas around the Sun centre. Concentrating on the last two solar minima, we
found out that there is very little variation in the radiance distribution of
the chromospheric spectral line \ion{He}{I} between these minima. The same
analysis shows a modest, although significant, 4\% variation in the radiance
distribution of the transition region spectral line \ion{O}{V}. These results
are comparable to those obtained by earlier studies employing other spectral
features, and they confirm that chromospheric indices display a small
variation, whereas in the TR a more significant reduction of the brighter
features is visible
Fine structures in the atmosphere above a sunspot umbra
We present simultaneous photospheric and chromospheric observations of the
trailing sunspot in NOAA 10904, obtained with the Swedish Solar Telescope (SST)
La Palma, Canary Islands. Time series of high resolution \ion{Ca}{ii}\,
images show transient jet-like structures in sunspot umbrae are elongated,
which we call umbral microjets. These jets are directed roughly parallel to
nearby penumbral microjets, suggesting that they are aligned with the
background magnetic field. In general, first a bright dot-like structure
appears, from which a jet later emerges, although some jets appear without an
associated chromospheric dot. Bright photospheric umbral dots are associated
with umbral microjets arising in the outer umbra. Nevertheless, a one-to-one
correspondence between jet-like events and underlying umbral dots is not seen.
They are typically less than 1\arcsec ~long and less than 0\farcs3 wide. The
typical lifetime of umbral microjets is around one minute. The brightness of
these structures increases from the center of the umbra towards the
umbra-penumbra boundary along with the brightness of the local background.Comment: 5 pages, 6 figures. Accepted for publication in A&A Lette
Discriminant analysis of solar bright points and faculae II. Contrast and morphology analysis
Taken at a high spatial resolution of 0.1 arcsec, Bright Points (BPs) are
found to coexist with faculae in images and the latter are often resolved as
adjacent striations. Understanding the properties of these different features
is fundamental to carrying out proxy magnetometry. To shed light on the
relationship between BPs and faculae, we studied them separately after the
application of a classification method, developed and described in a previous
paper) on active region images at various heliocentric angles. In this Paper,
we explore different aspects of the photometric properties of BPs and faculae,
namely their G-band contrast profiles, their peak contrast in G-band and
continuum, as well as morphological parameters. We find that: (1) the width of
the contrast profiles of the classified BPs and faculae are consistent with
studies of disk center BPs at and limb faculae, which indirectly confirms the
validity of our classification, (2) the profiles of limb faculae are limbward
skewed on average, while near disk center they exhibit both centerward and
limbward skewnesses due to the distribution of orientations of the faculae, (3)
the relation between the peak contrasts of BPs and faculae and their apparent
area discloses a trend reminiscent of magnetogram studies. The skewness of
facular profiles provides a novel constraint for 3D MHD models of faculae. As
suggested by the asymmetry and orientation of their contrast profiles, faculae
near disk center could be induced by inclined fields, while apparent BPs near
the limb seem to be in fact small faculae misidentified. The apparent area of
BPs and faculae could be possibly exploited for proxy magnetometry
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