184 research outputs found
Magnetohydrostatic equilibrium in starspots: dependences on color (T_{eff}) and surface gravity (g)
Temperature contrasts and magnetic field strengths of sunspot umbrae broadly
follow the thermal-magnetic relationship obtained from magnetohydrostatic
equilibrium. Using a compilation of recent observations, especially in
molecular bands, of temperature contrasts of starspots in cool stars, and a
grid of Kurucz stellar model atmospheres constructed to cover layers of
sub-surface convection zone, we examine how the above relationship scales with
effective temperature T_{eff}, surface gravity g and the associated changes in
opacity of stellar photospheric gas. We calculate expected field strengths in
starpots and find that a given relative reduction in temperatures (or the same
darkness contrasts) yield increasing field strengths against decreasing T_{eff}
due to a combination of pressure and opacity variations against T_{eff}.Comment: 4 pages, 3 figures, to appear in the Proceedings of IAUS 273:
"Physics of Sun and Star Spots", eds. D.P. Choudhary and K. Strassmeier 2010,
Cambridge University Pres
Contamination by Surface Effects of Time-distance Helioseismic Inversions for Sound Speed Beneath Sunspots
Using Doppler velocity data from the SOI/MDI instrument onboard the SoHO
spacecraft, we do time-distance helioseismic inversions for sound-speed
perturbations beneath 16 sunspots observed in high-resolution mode. We clearly
detect ring-like regions of enhanced sound speed beneath most sunspot
penumbrae, extending from near the surface to depths of about 3.5 Mm. Due to
their location and dependence on frequency bands of p-modes used, we believe
these rings to be artifacts produced by a surface signal probably associated
with the sunspot magnetic field.Comment: accepted by Ap
Dynamics of photospheric magnetic flux distribution and variations in solar RVs -- a study using HARPS-N solar and SDO observations
The distribution and evolution of photospheric magnetic field in sunspots,
plages and network, and variations in their relative flux content, play key
roles in radial velocity (RV) fluctuations observed in Sun-as-a-star spectra.
Differentiating and disentangling such magnetic contributions to RVs help in
building models to account for stellar activity signals in high precision RV
exoplanet searches. In this work, as earlier authors, we employ high-resolution
images of the solar magnetic field and continuum intensities from SDO/HMI to
understand the activity contributions to RVs from HARPS-N solar observations.
Using well observed physical relationships between strengths and fluxes of
photospheric magnetic fields, we show that the strong fields (spots, plages and
network) and the weak internetwork fields leave distinguishing features in
their contributions to the RV variability. We also find that the fill-factors
and average unsigned magnetic fluxes of different features correlate
differently with the RVs and hence warrant care in employing either of them as
a proxy for RV variations. In addition, we examine disk averaged UV intensities
at 1600 \r{A} and 1700 \r{A} wavelength bands imaged by SDO/AIA and their
performances as proxies for variations in different magnetic features. We find
that the UV intensities provide a better measure of contributions of plage
fields to RVs than the Ca II H-K emission indices, especially during high
activity levels when the latter tend to saturate.Comment: 18 pages (preprint format), 14 figures. Accepted by The Astrophysical
Journal (Sep, 2023
Solar meridional circulation from twenty-one years of SOHO/MDI and SDO/HMI observations: Helioseismic travel times and forward modeling in the ray approximation
The south-north travel-time differences are measured by applying
time-distance helioseismology to the MDI and HMI medium-degree Dopplergrams
covering May 1996-April 2017. Our data analysis corrects for several sources of
systematic effects: P-angle error, surface magnetic field effects, and
center-to-limb variations. An interpretation of the travel-time measurements is
obtained using a forward-modeling approach in the ray approximation. The
travel-time differences are similar in the southern hemisphere for cycles 23
and 24. However, they differ in the northern hemisphere between cycles 23 and
24. Except for cycle 24's northern hemisphere, the measurements favor a
single-cell meridional circulation model where the poleward flows persist down
to 0.8 , accompanied by local inflows toward the activity belts
in the near-surface layers. Cycle 24's northern hemisphere is anomalous:
travel-time differences are significantly smaller when travel distances are
greater than 20. This asymmetry between northern and southern
hemispheres during cycle 24 was not present in previous measurements (e.g.,
Rajaguru & Antia 2015), which assumed a different P-angle error correction
where south-north travel-time differences are shifted to zero at the equator
for all travel distances. In our measurements, the travel-time differences at
the equator are zero for travel distances less than 30, but they
do not vanish for larger travel distances. This equatorial offset for large
travel distances need not be interpreted as a deep cross-equator flow; it could
be due to the presence of asymmetrical local flows at the surface near the end
points of the acoustic ray paths.Comment: accepted for publication in A&
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