2,547 research outputs found
Solar radius and luminosity variations induced by the internal dynamo magnetic fields
Although the occurrence of solar irradiance variations induced by magnetic
surface features (e.g., sunspots, faculae, magnetic network) is generally
accepted, the existence of intrinsic luminosity changes due to the internal
magnetic fields is still controversial. This additional contribution is
expected to be accompanied by radius variations, and to be potentially
significant for the climate of the Earth. We aim to constrain theoretically the
radius and luminosity variations of the Sun that are due to the effect of the
variable magnetic fields in its interior associated with the dynamo cycle. We
have extended a one-dimensional stellar evolution code to include several
effects of the magnetic fields on the interior structure. We investigate
different magnetic configurations, based on both observational constraints and
on the output of state-of-the-art mean field dynamo models. We explore both
step-like and simply periodic time dependences of the magnetic field peak
strength. We find that the luminosity and radius variations are in anti-phase
and in phase, respectively, with the magnetic field strength. For peak magnetic
field strengths of the order of tens of kilogauss, luminosity variations
ranging between 10^{-6} and 10^{-3} (in modulus) and radius variations between
10^{-6} and 10^{-5} are obtained. Modest but significant radius variations (up
to 10^{-5} in relative terms) are obtained for magnetic fields of realistic
strength and geometry, providing a potentially observable signature of the
intrinsic variations. Establishing their existence in addition to the accepted
surface effects would have very important implications for the understanding of
solar-induced long-term trends on climate.Comment: 18 pages, 7 figures; accepted for publication in Astronomische
Nachrichte
The angular momentum transport by unstable toroidal magnetic fields
We demonstrate with a nonlinear MHD code that angular momentum can be
transported due to the magnetic instability of toroidal fields under the
influence of differential rotation, and that the resulting effective viscosity
may be high enough to explain the almost rigid-body rotation observed in
radiative stellar cores. Only stationary current-free fields and only those
combinations of rotation rates and magnetic field amplitudes which provide
maximal numerical values of the viscosity are considered. We find that the
dimensionless ratio of the effective over molecular viscosity, ;,
linearly grows with the Reynolds number of the rotating fluid multiplied with
the square-root of the magnetic Prandtl number - which is of order unity for
the considered red sub-giant KIC 7341231.
For the considered interval of magnetic Reynolds numbers - which is
restricted by numerical constraints of the nonlinear MHD code - there is a
remarkable influence of the magnetic Prandtl number on the relative importance
of the contributions of the Reynolds stress and the Maxwell stress to the total
viscosity, which is magnetically dominated only for Pm 0.5. We also
find that the magnetized plasma behaves as a non-Newtonian fluid, i.e. the
resulting effective viscosity depends on the shear in the rotation law. The
decay time of the differential rotation thus depends on its shear and becomes
longer and longer during the spin-down of a stellar core.Comment: Revised version. 7 pages, 9 figures; accepted for publication in A&
Operation of the AMS-02 TRD in Space
Abstract The AMS-02 detector was installed on May 2011 on the International Space Station and has since collected billions of cosmic ray events. AMS will measure with unprecedent precision cosmic ray spectra up to the TeV energy scale, achieving a sensitivity to the presence of anti-nuclei of one part in a billion, as well as providing important information on the origin of dark matter. A Transition Radiation Detector (TRD), filled with a Xe/CO2 mixture, is used to reach the sensitivity to positron identification needed for the detection of a neutralino dark matter candidate. The control of a gaseous detector in Space is a challenging task. The operational procedures, and the performances achieved, will be described
Angular momentum transport efficiency in post-main sequence low-mass stars
Context. Using asteroseismic techniques, it has recently become possible to
probe the internal rotation profile of low-mass (~1.1-1.5 Msun) subgiant and
red giant stars. Under the assumption of local angular momentum conservation,
the core contraction and envelope expansion occurring at the end of the main
sequence would result in a much larger internal differential rotation than
observed. This suggests that angular momentum redistribution must be taking
place in the interior of these stars. Aims. We investigate the physical nature
of the angular momentum redistribution mechanisms operating in stellar
interiors by constraining the efficiency of post-main sequence rotational
coupling. Methods. We model the rotational evolution of a 1.25 Msun star using
the Yale Rotational stellar Evolution Code. Our models take into account the
magnetic wind braking occurring at the surface of the star and the angular
momentum transport in the interior, with an efficiency dependent on the degree
of internal differential rotation. Results. We find that models including a
dependence of the angular momentum transport efficiency on the radial
rotational shear reproduce very well the observations. The best fit of the data
is obtained with an angular momentum transport coefficient scaling with the
ratio of the rotation rate of the radiative interior over that of the
convective envelope of the star as a power law of exponent ~3. This scaling is
consistent with the predictions of recent numerical simulations of the
Azimuthal Magneto-Rotational Instability. Conclusions. We show that an angular
momentum transport process whose efficiency varies during the stellar evolution
through a dependence on the level of internal differential rotation is required
to explain the observed post-main sequence rotational evolution of low-mass
stars.Comment: 8 pages, 6 figures; accepted for publication in Astronomy &
Astrophysic
Improved calibration of the radii of cool stars based on 3D simulations of convection: implications for the solar model
Main sequence, solar-like stars (M < 1.5 Msun) have outer convective
envelopes that are sufficiently thick to affect significantly their overall
structure. The radii of these stars, in particular, are sensitive to the
details of inefficient, super-adiabatic convection occurring in their outermost
layers. The standard treatment of convection in stellar evolution models, based
on the Mixing-Length Theory (MLT), provides only a very approximate description
of convection in the super-adiabatic regime. Moreover, it contains a free
parameter, alpha_MLT, whose standard calibration is based on the Sun, and is
routinely applied to other stars ignoring the differences in their global
parameters (e.g., effective temperature, gravity, chemical composition) and
previous evolutionary history. In this paper, we present a calibration of
alpha_MLT based on three-dimensional radiation-hydrodynamics (3D RHD)
simulations of convection. The value of alpha_MLT is adjusted to match the
specific entropy in the deep, adiabatic layers of the convective envelope to
the corresponding value obtained from the 3D RHD simulations, as a function of
the position of the star in the (log g, log T_eff) plane and its chemical
composition. We have constructed a model of the present-day Sun using such
entropy-based calibration. We find that its past luminosity evolution is not
affected by the entropy calibration. The predicted solar radius, however,
exceeds that of the standard model during the past several billion years,
resulting in a lower surface temperature. This illustrative calculation also
demonstrates the viability of the entropy approach for calibrating the radii of
other late-type stars.Comment: 16 pages, 14 figures, accepted for publication in the Astrophysical
Journa
Lower limit for differential rotation in members of young loose stellar associations
Surface differential rotation (SDR) plays a key role in dynamo models. SDR
estimates are therefore essential for constraining theoretical models. We
measure a lower limit to SDR in a sample of solar-like stars belonging to young
associations with the aim of investigating how SDR depends on global stellar
parameters in the age range (4-95 Myr). The rotation period of a solar-like
star can be recovered by analyzing the flux modulation caused by dark spots and
stellar rotation. The SDR and the latitude migration of dark-spots induce a
modulation of the detected rotation period. We employ long-term photometry to
measure the amplitude of such a modulation and to compute the quantity
DeltaOmega_phot =2p/P_min -2pi/P_max that is a lower limit to SDR. We find that
DeltaOmega_phot increases with the stellar effective temperature and with the
global convective turn-over time-scale tau_c. We find that DeltaOmega_phot is
proportional to Teff^2.18pm 0.65 in stars recently settled on the ZAMS. This
power law is less steep than those found by previous authors, but closest to
recent theoretical models. We find that DeltaOmega_phot steeply increases
between 4 and 30 Myr and that itis almost constant between 30 and 95 Myr in a 1
M_sun star. We find also that the relative shear increases with the Rossby
number Ro. Although our results are qualitatively in agreement with
hydrodynamical mean-field models, our measurements are systematically higher
than the values predicted by these models. The discrepancy between
DeltaOmega_phot measurements and theoretical models is particularly large in
stars with periods between 0.7 and 2 d. Such a discrepancy, together with the
anomalous SDR measured by other authors for HD 171488 (rotating in 1.31 d),
suggests that the rotation period could influence SDR more than predicted by
the models.Comment: 23 pages, 15 figures, 5 tables,accepted by Astronomy and Astrophysic
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