Evolved star water maser cloud size determined by star size

Richards, A. M. S.; Etoka, S.; Gray, M. D.; Lekht, E. E.; Mendoza-Torres, J. E.; Murakawa, K.; Rudnitskij, G. M.; Yates, J.

doi:10.1051/0004-6361/201219514

Cited by 56 publications

(84 citation statements)

References 73 publications

(106 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although an explanation in terms of instabilities, with an associated physical scale corresponding to an optimum growth rate, may at first appear to be at odds with the observed scaling with star size (Richards et al 2012), the observation and clumping theory may still be compatible. Recent work (Gray, Khamis and Amos, in preparation) on instabilities in a spherical geometry generates perturbations in terms of spherical harmonics that have a natural radial scaling as a multiple of the stellar radius.…”

Section: Origins Of Clumpingmentioning

confidence: 96%

The physics of water masers observable with ALMA and SOFIA: model predictions for evolved stars

Gray

Baudry

Richards

et al. 2015

Mon. Not. R. Astron. Soc.

Self Cite

View full text Add to dashboard Cite

We present the results of models that were designed to study all possible water maser transitions in the frequency range 0-1.91 THz, with particular emphasis on maser transitions that may be generated in evolved-star envelopes and observed with the ALMA and SOFIA telescopes. We used tens of thousands of radiative transfer models of both spin species of H 2 O, spanning a considerable parameter space in number density, kinetic temperature and dust temperature. Results, in the form of maser optical depths, have been summarized in a master table, Table 6. Maser transitions identified in these models were grouped according to loci of inverted regions in the density/kinetic temperature plane, a property clearly related to the dominant mode of pumping. A more detailed study of the effect of dust temperature on maser optical depth enabled us to divide the maser transitions into three groups: those with both collisional and radiative pumping schemes (22,96,209,321,325,395,941 and 1486 GHz), a much larger set that are predominantly radiatively pumped, and another large group with a predominantly collisional pump. The effect of accelerative and decelerative velocity shifts of up to 5 km s −1 was found to be generally modest, with the primary effect of reducing computed maser optical depths. More subtle asymmetric effects, dependent on line overlap, include maximum gains offset from zero shift by >1 km s −1 , but these effects were predominantly found under conditions of weak amplification. These models will allow astronomers to use multi-transition water maser observations to constrain physical conditions down to the size of individual masing clouds (size of a few astronomical units).

show abstract

Section: Origins Of Clumpingmentioning

confidence: 96%

The physics of water masers observable with ALMA and SOFIA: model predictions for evolved stars

Gray

Baudry

Richards

et al. 2015

Mon. Not. R. Astron. Soc.

Self Cite

View full text Add to dashboard Cite

show abstract

“…5), and could therefore be related to, e.g., an H 2 O or SiO maser clump (i.e. Richards et al 2011Richards et al , 2012.…”

Section: Morphology Of Rt Vir In the Mid-infraredmentioning

confidence: 99%

The wind of the M-type AGB star RT Virginis probed by VLTI/MIDI

Sacuto

Ramstedt

Höfner

et al. 2013

A&A

View full text Add to dashboard Cite

Aims. We study the circumstellar environment of the M-type AGB star RT Vir using mid-infrared high spatial resolution observations from the ESO-VLTI focal instrument MIDI. The aim of this study is to provide observational constraints on theoretical prediction that the winds of M-type AGB objects can be driven by photon scattering on iron-free silicate grains located in the close environment (about 2 to 3 stellar radii) of the star. Methods. We interpreted spectro-interferometric data, first using wavelength-dependent geometric models. We then used a selfconsistent dynamic model atmosphere containing a time-dependent description of grain growth for pure forsterite dust particles to reproduce the photometric, spectrometric, and interferometric measurements of RT Vir. Since the hydrodynamic computation needs stellar parameters as input, a considerable effort was first made to determine these parameters. Results. MIDI differential phases reveal the presence of an asymmetry in the stellar vicinity. Results from the geometrical modeling give us clues to the presence of aluminum and silicate dust in the close circumstellar environment (<5 stellar radii). Comparison between spectro-interferometric data and a self-consistent dust-driven wind model reveals that silicate dust has to be present in the region between 2 to 3 stellar radii to reproduce the 59 and 63 m baseline visibility measurements around 9.8 μm. This gives additional observational evidence in favor of winds driven by photon scattering on iron-free silicate grains located in the close vicinity of an M-type star. However, other sources of opacity are clearly missing to reproduce the 10−13 μm visibility measurements for all baselines.Conclusions. This study is a first attempt to understand the wind mechanism of M-type AGB stars by comparing photometric, spectrometric, and interferometric measurements with state-of-the-art, self-consistent dust-driven wind models. The agreement of the dynamic model atmosphere with interferometric measurements in the 8−10 μm spectral region gives additional observational evidence that the winds of M-type stars can be driven by photon scattering on iron-free silicate grains. Finally, a larger statistical study and progress in advanced self-consistent 3D modeling are still required to solve the remaining problems.

show abstract

“…The estimates of the mass loss rate for a red giantṀ lie within the range from 4 × 10 −6 (Neri et al 1998) to 3 × 10 −5 M yr −1 (Gonzalez Delgado et al 2003). In our model, the geometrical sizes of the gas-dust cloud and the distance from the cloud to the star correspond to the mean values of these parameters for the maser sources in the envelope of IK Tau (Bains et al 2003;Richards et al 2011Richards et al , 2012. The turbulent velocity in the gas-dust cloud is taken to be 1.5 km s −1 (Decin 2012).…”

Section: Model Parametersmentioning

confidence: 99%

“…The turbulent velocity in the gas-dust cloud is taken to be 1.5 km s −1 (Decin 2012). The gas velocity gradient in the cloud is assumed to be 0.22 km s −1 AU −1 -the mean stellar wind velocity gradient in the inner region of the gas-dust envelope around IK Tau, where the H 2 O maser emission is observed (Richards et al 2012). In the inner regions of the gas-dust envelopes around cool late-type stars, hydrogen is contained mainly in the form of H 2 molecules (Glassgold and Huggins 1983).…”

Section: Model Parametersmentioning

confidence: 99%

“…To estimate the mean velocity and mean velocity gradient of the gas, we used observational data on the velocity distribution of H 2 O maser sources in the circumstellar envelope of IK Tau (Richards et al 2011(Richards et al , 2012. In our calculations of the gas temperature, we consider the gas heating and cooling rates averaged over the cloud, q i = 1 H H 0 dz q i (z).…”

Section: The Thermal Balance Of Gasmentioning

confidence: 99%

See 1 more Smart Citation

H2O maser emission in circumstellar envelopes around AGB stars: Physical conditions in gas-dust clouds

Nesterenok

2013

Astron. Lett.

View full text Add to dashboard Cite

The pumping of 22.2-GHz H 2 O masers in the circumstellar envelopes of asymptotic giant branch stars has been simulated numerically. The physical parameters adopted in the calculations correspond to those of the circumstellar envelope around IK Tau. The one-dimensional plane-parallel structure of the gas-dust cloud is considered. The statistical equilibrium equations for the H 2 O level populations and the thermal balance equations for the gas-dust cloud are solved self-consistently. The calculations take into account 410 rotational levels belonging to the five lowest vibrational levels of H 2 O. The stellar radiation field is shown to play an important role in the thermal balance of the gas-dust cloud due to the absorption of emission in rotational-vibrational H 2 O lines. The dependence of the gain in the 22.2-GHz maser line on the gas density and H 2 O number density in the gas-dust cloud is investigated. Gas densities close to the mean density of the stellar wind, 10 7 -10 8 cm −3 , and a high relative H 2 O abundance, more than 10 −4 , have been found to be the most likely physical conditions in maser sources.

show abstract

Evolved star water maser cloud size determined by star size

Cited by 56 publications

References 73 publications

The physics of water masers observable with ALMA and SOFIA: model predictions for evolved stars

The physics of water masers observable with ALMA and SOFIA: model predictions for evolved stars

The wind of the M-type AGB star RT Virginis probed by VLTI/MIDI

H2O maser emission in circumstellar envelopes around AGB stars: Physical conditions in gas-dust clouds

Contact Info

Product

Resources

About