119 research outputs found
Helioseismology challenges models of solar convection
Convection is the mechanism by which energy is transported through the
outermost 30% of the Sun. Solar turbulent convection is notoriously difficult
to model across the entire convection zone where the density spans many orders
of magnitude. In this issue of PNAS, Hanasoge et al. (2012) employ recent
helioseismic observations to derive stringent empirical constraints on the
amplitude of large-scale convective velocities in the solar interior. They
report an upper limit that is far smaller than predicted by a popular
hydrodynamic numerical simulation.Comment: Printed in the Proceedings of the National Academy of Sciences (2
pages, 1 figure). Available at
http://www.pnas.org/cgi/doi/10.1073/pnas.120887510
Problems in computational helioseismology
We discuss current advances in forward and inverse modeling for local
helioseismology. We report theoretical uniqueness results, in particular the
Novikov-Agaltsov reconstruction algorithm, which is relevant to solving the
non-linear inverse problem of time-distance helioseismology (finite amplitude
pertubations to the medium). Numerical experiments were conducted to determine
the number of frequencies required to reconstruct density and sound speed in
the solar interior.Comment: Oberwolfach Report, Computational Inverse Problems for Partial
Differential Equations, 14 May - 20 May 2017.
https://www.mfo.de/occasion/1720/www_vie
Propagation of seismic waves through a spatio-temporally fluctuating medium: Homogenization
Measurements of seismic wave travel times at the photosphere of the Sun have
enabled inferences of its interior structure and dynamics. In interpreting
these measurements, the simplifying assumption that waves propagate through a
temporally stationary medium is almost universally invoked. However, the Sun is
in a constant state of evolution, on a broad range of spatio-temporal scales.
At the zero wavelength limit, i.e., when the wavelength is much shorter than
the scale over which the medium varies, the WKBJ (ray) approximation may be
applied. Here, we address the other asymptotic end of the spectrum, the
infinite wavelength limit, using the technique of homogenization. We apply
homogenization to scenarios where waves are propagating through rapidly varying
media (spatially and temporally), and derive effective models for the media.
One consequence is that a scalar sound speed becomes a tensorial wavespeed in
the effective model and anisotropies can be induced depending on the nature of
the perturbation. The second term in this asymptotic two-scale expansion, the
so-called corrector, contains contributions due to higher-order scattering,
leading to the decoherence of the wavefield. This decoherence may be causally
linked to the observed wave attenuation in the Sun. Although the examples we
consider here consist of periodic arrays of perturbations to the background,
homogenization may be extended to ergodic and stationary random media. This
method may have broad implications for the manner in which we interpret seismic
measurements in the Sun and for modeling the effects of granulation on the
scattering of waves and distortion of normal-mode eigenfunctions.Comment: 17 pages, 6 figures, in press, Ap
Solar-cycle variation of the rotational shear near the solar surface
Helioseismology has revealed that the angular velocity of the Sun increases
with depth in the outermost 35 Mm of the Sun. Recently, we have shown that the
logarithmic radial gradient () in the upper 10~Mm
is close to from the equator to latitude.We aim to measure the
temporal variation of the rotational shear over solar cycle 23 and the rising
phase of cycle 24 (1996-2015). We used f mode frequency splitting data spanning
1996 to 2011 from the Michelson Doppler Imager (MDI) and 2010 to 2015 from the
Helioseismic Magnetic Imager (HMI). In a first for such studies, the f mode
frequency splitting data were obtained from 360-day time series. We used the
same method as in our previous work for measuring from
the equator to latitude in the outer 13~Mm of the Sun. Then, we
calculated the variation of the gradient at annual cadence relative to the
average over 1996 to 2015. We found the rotational shear at low latitudes
( to ) to vary in-phase with the solar activity, varying by
\% over the period 1996 to 2015. At high latitudes ( to
), we found rotational shear to vary in anti-phase with the solar
activity. By comparing the radial gradient obtained from the splittings of the
360-day and the corresponding 72-day time series of HMI and MDI data, we
suggest that the splittings obtained from the 72-day HMI time series suffer
from systematic errors. We provide a quantitative measurement of the temporal
variation of the outer part of the near surface shear layer which may provide
useful constraints on dynamo models and differential rotation theory.Comment: 5 pages, 6 figure
Interpretation of Helioseismic Travel Times - Sensitivity to Sound Speed, Pressure, Density, and Flows
Time-distance helioseismology uses cross-covariances of wave motions on the
solar surface to determine the travel times of wave packets moving from one
surface location to another. We review the methodology to interpret travel-time
measurements in terms of small, localized perturbations to a horizontally
homogeneous reference solar model. Using the first Born approximation, we
derive and compute 3D travel-time sensitivity (Fr\'echet) kernels for
perturbations in sound-speed, density, pressure, and vector flows. While
kernels for sound speed and flows had been computed previously, here we extend
the calculation to kernels for density and pressure, hence providing a complete
description of the effects of solar dynamics and structure on travel times. We
treat three thermodynamic quantities as independent and do not assume
hydrostatic equilibrium. We present a convenient approach to computing damped
Green's functions using a normal-mode summation. The Green's function must be
computed on a wavenumber grid that has sufficient resolution to resolve the
longest lived modes. The typical kernel calculations used in this paper are
computer intensive and require on the order of 600 CPU hours per kernel.
Kernels are validated by computing the travel-time perturbation that results
from horizontally-invariant perturbations using two independent approaches. At
fixed sound-speed, the density and pressure kernels are approximately related
through a negative multiplicative factor, therefore implying that perturbations
in density and pressure are difficult to disentangle. Mean travel-times are not
only sensitive to sound-speed, density and pressure perturbations, but also to
flows, especially vertical flows. Accurate sensitivity kernels are needed to
interpret complex flow patterns such as convection
Fragile detection of solar g modes by Fossat et al
The internal gravity modes of the Sun are notoriously difficult to detect,
and the claimed detection of gravity modes presented in Fossat et al. 2017 is
thus very exciting. Given the importance of these modes for understanding solar
structure and dynamics, the results must be robust. While Fossat et al. 2017
described their method and parameter choices in detail, the sensitivity of
their results to several parameters were not presented. Therefore, we test the
sensitivity to a selection of them. The most concerning result is that the
detection vanishes when we adjust the start time of the 16.5 year velocity time
series by a few hours. We conclude that this reported detection of gravity
modes is extremely fragile and should be treated with utmost caution.Comment: 15 pages, 11 Figure
Revisiting the exomoon candidate signal around Kepler-1625b
Transit photometry of the exoplanet candidate Kepler-1625b has recently been
interpreted to show hints of a moon. We aim to clarify whether the exomoon-like
signal is really caused by a large object in orbit around Kepler-1625b. We
explore several detrending procedures, i.e. polynomials and the Cosine
Filtering with Autocorrelation Minimization (CoFiAM). We then supply a light
curve simulator with the co-planar orbital dynamics of the system and fit the
resulting planet-moon transit light curves to the Kepler data. We employ the
Bayesian Information Criterion (BIC) to assess whether a single planet or a
planet-moon system is a more likely interpretation of the light curve
variations. We carry out a blind hare-and-hounds exercise using many noise
realizations by injecting simulated transits into different out-of-transit
parts of the original Kepler-1625 data: 100 sequences with 3 synthetic transits
of a Kepler-1625b-like planet and 100 sequences with 3 synthetic transits of
this planet with a Neptune-sized moon. The statistical significance and
characteristics of the exomoon-like signal strongly depend on the detrending
method, and the data chosen for detrending, and on the treatment of gaps in the
light curve. Our injection-retrieval experiment shows evidence for moons in
about 10% of those light curves that do not contain an injected moon.
Strikingly, many of these false-positive moons resemble the exomoon candidate.
We recover up to about half of the injected moons, depending on the detrending
method, with radii and orbital distances broadly corresponding to the injected
values. A BIC of -4.9 for the CoFiAM-based detrending indicates an
exomoon around Kepler-1625b. This solution, however, is only one out of many
and we find very different solutions depending on the details of the detrending
method. It is worrying that the detrending is key to the interpretation of the
data.Comment: 16 pages, 12 figures. Accepted for publication by A&
Generalization of the noise model for time-distance helioseismology
In time-distance helioseismology, information about the solar interior is
encoded in measurements of travel times between pairs of points on the solar
surface. Travel times are deduced from the cross-covariance of the random wave
field. Here we consider travel times and also products of travel times as
observables. They contain information about e.g. the statistical properties of
convection in the Sun. The basic assumption of the model is that noise is the
result of the stochastic excitation of solar waves, a random process which is
stationary and Gaussian. We generalize the existing noise model (Gizon and
Birch 2004) by dropping the assumption of horizontal spatial homogeneity. Using
a recurrence relation, we calculate the noise covariance matrices for the
moments of order 4, 6, and 8 of the observed wave field, for the moments of
order 2, 3 and 4 of the cross-covariance, and for the moments of order 2, 3 and
4 of the travel times. All noise covariance matrices depend only on the
expectation value of the cross-covariance of the observed wave field. For
products of travel times, the noise covariance matrix consists of three terms
proportional to , , and , where is the duration of the
observations. For typical observation times of a few hours, the term
proportional to dominates and , where the are arbitrary travel times. This
result is confirmed for travel times by Monte Carlo simulations and
comparisons with SDO/HMI observations. General and accurate formulae have been
derived to model the noise covariance matrix of helioseismic travel times and
products of travel times. These results could easily be generalized to other
methods of local helioseismology, such as helioseismic holography and ring
diagram analysis
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