13 research outputs found
Solar Magnetic Field Signatures in Helioseismic Splitting Coefficients
Normal modes of oscillation of the Sun are useful probes of the solar
interior. In this work, we use the even-order splitting coefficients to study
the evolution of magnetic fields in the convection zone over solar cycle 23,
assuming that the frequency splitting is only due to rotation and a large scale
magnetic field. We find that the data are best fit by a combination of a
poloidal field and a double-peaked near-surface toroidal field. The toroidal
fields are centered at r=0.999R_solar and r=0.996R_solar and are confined to
the near-surface layers. The poloidal field is a dipole field. The peak
strength of the poloidal field is 124 +/- 17G. The toroidal field peaks at 380
+/- 30G and 1.4 +/- 0.2kG for the shallower and deeper fields respectively. The
field strengths are highly correlated with surface activity. The toroidal field
strength shows a hysteresis-like effect when compared to the global 10.7 cm
radio flux. The poloidal field strength shows evidence of saturation at high
activity.Comment: 10 pages, accepted for publication in Ap
Evidence of a Quasi-periodic Global-scale Oscillation in the Near-Surface Shear Layer of the Sun
We present evidence of hitherto undiscovered global-scale oscillations in the
near-surface shear layer of the Sun. These oscillations are seen as large scale
variations of radial shear in both the zonal and meridional flows relative to
their mean values. The variations cover all or most of a visible hemisphere,
and reverse with a timescale on the order of a solar rotation. A large annual
variation in the meridional shear anomaly is understandable in terms of the
tilt of the rotation axis, but the rapid oscillations of the shear anomalies in
both zonal and the meridional directions appear to be modulated in a more
complex, not-quite annual way, although the latter are also strongly modulated
by the projected rotational axis angle. Small-scale anomalies in the
neighborhood of active regions lend support to their solar origin and physical
interpretation. These results were obtained by analyzing ring-diagram fits of
low-order modes in high-resolution Doppler data from the Helioseismic and
Magnetic Imager on the Solar Dynamics Observatory.Comment: Accepted for publication in Astrophysical Journal Letter
On-Orbit Performance of the Helioseismic and Magnetic Imager Instrument onboard the Solar Dynamics Observatory
The Helioseismic and Magnetic Imager (HMI) instrument is a major component of
NASA's Solar Dynamics Observatory (SDO) spacecraft. Since beginning normal
science operations on 1 May 2010, HMI has operated with remarkable continuity,
e.g. during the more than five years of the SDO prime mission that ended 30
September 2015, HMI collected 98.4% of all possible 45-second velocity maps;
minimizing gaps in these full-disk Dopplergrams is crucial for helioseismology.
HMI velocity, intensity, and magnetic-field measurements are used in numerous
investigations, so understanding the quality of the data is important. We
describe the calibration measurements used to track HMI performance and detail
trends in important instrument parameters during the mission. Regular
calibration sequences provide information used to improve and update the HMI
data calibration. The set-point temperature of the instrument front window and
optical bench is adjusted regularly to maintain instrument focus, and changes
in the temperature-control scheme have been made to improve stability in the
observable quantities. The exposure time has been changed to compensate for a
15% decrease in instrument throughput. Measurements of the performance of the
shutter and tuning mechanisms show that they are aging as expected and continue
to perform according to specification. Parameters of the tunable-optical-filter
elements are regularly adjusted to account for drifts in the central
wavelength. Frequent measurements of changing CCD-camera characteristics, such
as gain and flat field, are used to calibrate the observations. Infrequent
expected events, such as eclipses, transits, and spacecraft off-points,
interrupt regular instrument operations and provide the opportunity to perform
additional calibration. Onboard instrument anomalies are rare and seem to occur
quite uniformly in time. The instrument continues to perform very well.Comment: 50 pages, 18 figures, 20 table
Solar Cycle Related Changes at the Base of the Convection Zone
The frequencies of solar oscillations are known to change with solar
activity. We use Principal Component Analysis to examine these changes with
high precision. In addition to the well-documented changes in solar normal mode
oscillations with activity as a function of frequency, which originate in the
surface layers of the Sun, we find a small but statistically significant change
in frequencies with an origin at and below the base of the convection zone. We
find that at r=(0.712^{+0.0097}_{-0.0029})R_sun, the change in sound speed is
\delta c^2 / c^2 = (7.23 +/- 2.08) x 10^{-5} between high and low activity.
This change is very tightly correlated with solar activity. In addition, we use
the splitting coefficients to examine the latitudinal structure of these
changes. We find changes in sound speed correlated with surface activity for r
>~ 0.9R_sun.Comment: 29 pages, 11 figures, accepted for publication in Ap
Two-Dimensional Helioseismic Power, Phase, and Coherence Spectra of {\it Solar Dynamics Observatory} Photospheric and Chromospheric Observables
While the {\it Helioseismic and Magnetic Imager} (HMI) onboard the {\it Solar
Dynamics Observatory} (SDO) provides Doppler velocity [], continuum
intensity [], and line-depth [] observations, each of which is
sensitive to the five-minute acoustic spectrum, the {\it Atmospheric Imaging
Array} (AIA) also observes at wavelengths -- specifically the 1600 and 1700
Angstrom bands -- that are partly formed in the upper photosphere and have good
sensitivity to acoustic modes. In this article we consider the characteristics
of the spatio--temporal Fourier spectra in AIA and HMI observables for a
15-degree region around NOAA Active Region 11072. We map the
spatio--temporal-power distribution for the different observables and the HMI
Line Core [], or Continuum minus Line Depth, and the phase and coherence
functions for selected observable pairs, as a function of position and
frequency. Five-minute oscillation power in all observables is suppressed in
the sunspot and also in plage areas. Above the acoustic cut-off frequency, the
behaviour is more complicated: power in HMI is still suppressed in the
presence of surface magnetic fields, while power in HMI and the AIA bands
is suppressed in areas of surface field but enhanced in an extended area around
the active region, and power in HMI is enhanced in a narrow zone around
strong-field concentrations and suppressed in a wider surrounding area. The
relative phase of the observables, and their cross-coherence functions, are
also altered around the active region. These effects may help us to understand
the interaction of waves and magnetic fields in the different layers of the
photosphere, and will need to be taken into account in multi-wavelength local
helioseismic analysis of active regions.Comment: 18 pages, 15 figures, to be published in Solar Physic
Detection of solar-like oscillations from Kepler photometry of the open cluster NGC 6819
Asteroseismology of stars in clusters has been a long-sought goal because the
assumption of a common age, distance and initial chemical composition allows
strong tests of the theory of stellar evolution. We report results from the
first 34 days of science data from the Kepler Mission for the open cluster NGC
6819 -- one of four clusters in the field of view. We obtain the first clear
detections of solar-like oscillations in the cluster red giants and are able to
measure the large frequency separation and the frequency of maximum oscillation
power. We find that the asteroseismic parameters allow us to test
cluster-membership of the stars, and even with the limited seismic data in
hand, we can already identify four possible non-members despite their having a
better than 80% membership probability from radial velocity measurements. We
are also able to determine the oscillation amplitudes for stars that span about
two orders of magnitude in luminosity and find good agreement with the
prediction that oscillation amplitudes scale as the luminosity to the power of
0.7. These early results demonstrate the unique potential of asteroseismology
of the stellar clusters observed by Kepler.Comment: 5 pages, 4 figures, accepted by ApJ (Lett.
Evidence of a Quasiperiodic Global-scale Oscillation in the Near-surface Shear Layer of the Sun
We present evidence of hitherto undiscovered global-scale oscillations in the near-surface shear layer of the Sun. These oscillations are seen as large-scale variations of radial shear in both the zonal and meridional flows relative to their mean values. The variations cover all or most of a visible hemisphere, and reverse with a timescale on the order of a solar rotation. A large annual variation in the meridional shear anomaly is understandable in terms of the tilt of the rotation axis, but the rapid oscillations of the shear anomalies in both zonal and the meridional directions appear to be modulated in a more complex, not-quite-annual way, although the latter are also strongly modulated by the projected rotational axis angle. Small-scale anomalies in the neighborhood of active regions lend support to their solar origin and physical interpretation. These results were obtained by analyzing ring-diagram fits of low-order modes in high-resolution Doppler data from the Helioseismic and Magnetic Imager on the Solar Dynamics Observatory