312 research outputs found
Atmospheres and wind properties of non-spherical AGB stars
The wind-driving mechanism of asymptotic giant branch (AGB) stars is commonly
attributed to a two-step process: first, gas in the stellar atmosphere is
levitated by shockwaves caused by stellar pulsation, then accelerated outwards
by radiative pressure on newly formed dust, inducing a wind. Dynamical
modelling of such winds usually assumes a spherically symmetric star. We
explore the potential consequences of complex stellar surface structures, as
predicted by three-dimensional (3D) star-in-a-box modelling of M-type AGB
stars, on the resulting wind properties with the aim to improve the current
wind models. Two different modelling approaches are used; the COBOLD 3D
star-in-a-box code to simulate the convective, pulsating interior and lower
atmosphere of the star, and the DARWIN one-dimensional (1D) code to describe
the dynamical atmosphere where the wind is accelerated. The gas dynamics of the
inner atmosphere region at distances of , which both modelling
approaches simulate, are compared. Dynamical properties and luminosity
variations derived from COBOLD interior models are used as input for the
inner boundary in DARWIN wind models in order to emulate the effects of giant
convection cells and pulsation, and explore their influence on the dynamical
properties. The COBOLD models are inherently anisotropic, with non-uniform
shock fronts and varying luminosity amplitudes, in contrast to the spherically
symmetrical DARWIN wind models. DARWIN wind models with COBOLD-derived
inner boundary conditions produced wind velocities and mass-loss rates
comparable to the standard DARWIN models, however the winds show large density
variations on time-scales of 10-20 years.Comment: 13 pages, 12 figures, Accepted for publication in A&
Exploring wind-driving dust species in cool luminous giants III. Wind models for M-type AGB stars: dynamic and photometric properties
Stellar winds observed in asymptotic giant branch (AGB) stars are usually
attributed to a combination of stellar pulsations and radiation pressure on
dust. Shock waves triggered by pulsations propagate through the atmosphere,
compressing the gas and lifting it to cooler regions, which create favourable
conditions for grain growth. If sufficient radiative acceleration is exerted on
the newly formed grains through absorption or scattering of stellar photons, an
outflow can be triggered. Strong candidates for wind-driving dust species in
M-type AGB stars are magnesium silicates (MgSiO and MgSiO). Such
grains can form close to the stellar surface, they consist of abundant
materials and, if they grow to sizes comparable to the wavelength of the
stellar flux maximum, they experience strong acceleration by photon scattering.
We use a frequency-dependent radiation-hydrodynamics code with a detailed
description for the growth of MgSiO grains to calculate the first
extensive set of time-dependent wind models for M-type AGB stars. The resulting
wind properties, visual and near-IR photometry and mid-IR spectra are compared
with observations.We show that the models can produce outflows for a wide range
of stellar parameters. We also demonstrate that they reproduce observed
mass-loss rates and wind velocities, as well as visual and near-IR photometry.
However, the current models do not show the characteristic silicate features at
10 and 18 m as a result of the cool temperature of MgSiO grains in
the wind. Including a small amount of Fe in the grains further out in the
circumstellar envelope will increase the grain temperature and result in
pronounced silicate features, without significantly affecting the photometry in
the visual and near-IR wavelength regions.Comment: 11 pages, 14 figure
Pulsation-induced atmospheric dynamics in M-type AGB stars. Effects on wind properties, photometric variations and near-IR CO line profiles
Wind-driving in asymptotic giant branch (AGB) stars is commonly attributed to
a two-step process. First, matter in the stellar atmosphere is levitated by
shock waves, induced by stellar pulsation, and second, this matter is
accelerated by radiation pressure on dust, resulting in a wind. In dynamical
atmosphere and wind models the effects of the stellar pulsation are often
simulated by a simplistic prescription at the inner boundary. We test a sample
of dynamical models for M-type AGB stars, for which we kept the stellar
parameters fixed to values characteristic of a typical Mira variable but varied
the inner boundary condition. The aim was to evaluate the effect on the
resulting atmosphere structure and wind properties. The results of the models
are compared to observed mass-loss rates and wind velocities, photometry, and
radial velocity curves, and to results from 1D radial pulsation models.
Dynamical atmosphere models are calculated, using the DARWIN code for different
combinations of photospheric velocities and luminosity variations. The inner
boundary is changed by introducing an offset between maximum expansion of the
stellar surface and the luminosity and/or by using an asymmetric shape for the
luminosity variation. Models that resulted in realistic wind velocities and
mass-loss rates, when compared to observations, also produced realistic
photometric variations. For the models to also reproduce the characteristic
radial velocity curve present in Mira stars (derived from CO
lines), an overall phase shift of 0.2 between the maxima of the luminosity and
radial variation had to be introduced. We find that a group of models with
different boundary conditions (29 models, including the model with standard
boundary conditions) results in realistic velocities and mass-loss rates, and
in photometric variations
Tomography of silicate dust around M-type AGB stars I. Diagnostics based on dynamical models
The heavy mass loss observed in evolved asymptotic giant branch stars is
usually attributed to a two-step process: atmospheric levitation by
pulsation-induced shock waves, followed by radiative acceleration of newly
formed dust grains. Detailed wind models suggest that the outflows of M-type
AGB stars may be triggered by photon scattering on Fe-free silicates with grain
sizes of about 0.1 - 1 m. Due to the low grain temperature, these Fe-free
silicates can condense close to the star, but they do not produce the
characteristic mid-IR features that are often observed in M-type AGB stars.
However, it is probable that the silicate grains are gradually enriched with Fe
as they move away from the star, to a degree where the grain temperature stays
below the sublimation temperature, but is high enough to produce emission
features. We investigate whether differences in grain temperature in the inner
wind region, which are related to changes in the grain composition, can be
detected with current interferometric techniques, in order to put constraints
on the wind mechanism. To investigate this we use radial structures of the
atmosphere and wind of an M-type AGB star, produced with the 1D
radiation-hydrodynamical code DARWIN. The spectral energy distribution is found
to be a poor indicator of different temperature profiles and therefore is not a
good tool for distinguishing different scenarios of changing grain composition.
However, spatially resolved interferometric observations have promising
potential. They show signatures even for Fe-free silicates (found at 2-3
stellar radii), in contrast to the spectral energy distribution. Observations
with baselines that probe spatial scales of about 4 stellar radii and beyond
are suitable for tracing changes in grain composition, since this is where
effects of Fe enrichment should be found.Comment: Accepted for publication in Section 8. Stellar atmospheres of
Astronomy and Astrophysics. The official date of acceptance is 07/09/2017. 9
pages, 7 figures, 4 figures in appendi
Dust-driven winds of AGB stars: The critical interplay of atmospheric shocks and luminosity variations
Winds of AGB stars are thought to be driven by a combination of
pulsation-induced shock waves and radiation pressure on dust. In dynamic
atmosphere and wind models, the stellar pulsation is often simulated by
prescribing a simple sinusoidal variation in velocity and luminosity at the
inner boundary of the model atmosphere. We experiment with different forms of
the luminosity variation in order to assess the effects on the wind velocity
and mass-loss rate, when progressing from the simple sinusoidal recipe towards
more realistic descriptions. Using state-of-the-art dynamical models of C-rich
AGB stars, a range of different asymmetric shapes of the luminosity variation
and a range of phase shifts of the luminosity variation relative to the radial
variation are tested. These tests are performed on two stellar atmosphere
models. The first model has dust condensation and, as a consequence, a stellar
wind is triggered, while the second model lacks both dust and wind. The first
model with dust and stellar wind is very sensitive to moderate changes in the
luminosity variation. There is a complex relationship between the luminosity
minimum, and dust condensation: changing the phase corresponding to minimum
luminosity can either increase or decrease mass-loss rate and wind velocity.
The luminosity maximum dominates the radiative pressure on the dust, which in
turn, is important for driving the wind. These effects of changed luminosity
variation are coupled with the dust formation. In contrast there is very little
change to the structure of the model without dust. Changing the luminosity
variation, both by introducing a phase shift and by modifying the shape,
influences wind velocity and the mass-loss rate. To improve wind models it
would probably be desirable to extract boundary conditions from 3D dynamical
interior models or stellar pulsation models.Comment: 11 pages, 13 figures, accepted for publication in A&
Three-component modeling of C-rich AGB star winds I. Method and first results
Radiative acceleration of newly-formed dust grains and transfer of momentum
from the dust to the gas plays an important role for driving winds of AGB
stars. Therefore a detailed description of the interaction of gas and dust is a
prerequisite for realistic models of such winds. In this paper we present the
method and first results of a three-component time-dependent model of
dust-driven AGB star winds. With the model we plan to study the role and
effects of the gas-dust interaction on the mass loss and wind formation. The
wind model includes separate conservation laws for each of the three components
of gas, dust and the radiation field and is developed from an existing model
which assumes position coupling between the gas and the dust. As a new feature
we introduce a separate equation of motion for the dust component in order to
fully separate the dust phase from the gas phase. The transfer of mass, energy
and momentum between the phases is treated by interaction terms. We also carry
out a detailed study of the physical form and influence of the momentum
transfer term (the drag force) and three approximations to it. In the present
study we are interested mainly in the effect of the new treatment of the dust
velocity on dust-induced instabilities in the wind. As we want to study the
consequences of the additional freedom of the dust velocity on the model we
calculate winds both with and without the separate dust equation of motion. The
wind models are calculated for several sets of stellar parameters. We find that
there is a higher threshold in the carbon/oxygen abundance ratio at which winds
form in the new model. The winds of the new models, which include drift, differ
from the previously stationary winds, and the winds with the lowest mass loss
rates no longer form.Comment: 15 pages, 5 figures, accepted by A&
An extensive grid of DARWIN models for M-type AGB stars I. Mass-loss rates and other properties of dust-driven winds
The purpose of this work is to present an extensive grid of dynamical
atmosphere and wind models for M-type AGB stars, covering a wide range of
relevant stellar parameters. We used the DARWIN code, which includes
frequency-dependent radiation-hydrodynamics and a time-dependent description of
dust condensation and evaporation, to simulate the dynamical atmosphere. The
wind-driving mechanism is photon scattering on submicron-sized MgSiO
grains. The grid consists of models, with luminosities from
to and
effective temperatures from 2200K to 3400K. For the first time different
current stellar masses are explored with M-type DARWIN models, ranging from
0.75M to 3M. The modelling results are radial atmospheric
structures, dynamical properties such as mass-loss rates and wind velocities,
and dust properties (e.g. grain sizes, dust-to-gas ratios, and degree of
condensed Si). We find that the mass-loss rates of the models correlate
strongly with luminosity. They also correlate with the ratio :
increasing by an order of magnitude increases the mass-loss rates by
about three orders of magnitude, which may naturally create a superwind regime
in evolution models. There is, however, no discernible trend of mass-loss rate
with effective temperature, in contrast to what is found for C-type AGB stars.
We also find that the mass-loss rates level off at luminosities higher than
, and consequently at pulsation periods longer
than days. The final grain radii range from 0.25 micron to 0.6
micron. The amount of condensed Si is typically between 10% and 40%, with
gas-to-dust mass ratios between 500 and 4000.Comment: Accepted to A&A, 17 pages, 15 figure
Exploring wind-driving dust species in cool luminous giants II. Constraints from photometry of M-type AGB stars
The heavy mass loss observed in evolved asymptotic giant branch (AGB) stars
is usually attributed to a two-stage process: atmospheric levitation by
pulsation-induced shock waves, followed by radiative acceleration of newly
formed dust grains. The dust transfers momentum to the surrounding gas through
collisions and thereby triggers a general outflow. Radiation-hydrodynamical
models of M-type AGB stars suggest that these winds can be driven by photon
scattering -- in contrast to absorption -- on Fe-free silicate grains of sizes
0.1--1\,m. In this paper we study photometric constraints for wind-driving
dust species in M-type AGB stars, as part of an ongoing effort to identify
likely candidates among the grain materials observed in circumstellar
envelopes. To investigate the scenario of stellar winds driven by photon
scattering on dust, and to explore how different optical and chemical
properties of wind-driving dust species affect photometry we focus on two sets
of dynamical models atmospheres: (i) models using a detailed description for
the growth of MgSiO grains, taking into account both scattering and
absorption cross-sections when calculating the radiative acceleration, and (ii)
models using a parameterized dust description, constructed to represent
different chemical and optical dust properties. By comparing synthetic
photometry from these two sets of models to observations of M-type AGB stars we
can provide constraints on the properties of wind-driving dust species.
Photometry from wind models with a detailed description for the growth of
MgSiO grains reproduces well both the values and the time-dependent
behavior of observations of M-type AGB stars, providing further support for the
scenario of winds driven by photon scattering on dust.Comment: Accepted for publication in A&A. 15 pages, 14 figure
- …