LBT/LUCIFER near-infrared spectroscopy of PV Cephei

Garatti, A. Caratti o; Lopez, R. Garcia; Weigelt, G.; Тамбовцева, Л. В.; Гринин, В. П.; Wheelwright, H. E.; Ilee, J. D.

doi:10.1051/0004-6361/201321418

Cited by 21 publications

(28 citation statements)

References 90 publications

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“…This suggests that any ejection episode might be highly asymmetric, as also discussed by other authors (e.g. Melnikov et al 2008Melnikov et al , 2009Caratti o Garatti et al 2013;Cesaroni et al 2013).…”

Section: Centimetre Emissionsupporting

confidence: 65%

Radio outburst from a massive (proto)star

Cesaroni

Moscadelli

Neri

et al. 2018

A&A

Self Cite

102

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Context. Recent observations of the massive young stellar object S255 NIRS 3 have revealed a large increase in both methanol maser flux density and IR emission, which have been interpreted as the result of an accretion outburst, possibly due to instabilities in a circumstellar disk. This indicates that this type of accretion event could be common in young/forming early-type stars and in their lower mass siblings, and supports the idea that accretion onto the star may occur in a non-continuous way. Aims. As accretion and ejection are believed to be tightly associated phenomena, we wanted to confirm the accretion interpretation of the outburst in S255 NIRS 3 by detecting the corresponding burst of the associated thermal jet. Methods. We monitored the radio continuum emission from S255 NIRS 3 at four bands using the Karl G. Jansky Very Large Array. The millimetre continuum emission was also observed with both the Northern Extended Millimeter Array of IRAM and the Atacama Large Millimeter/submillimeter Array. Results. We have detected an exponential increase in the radio flux density from 6 to 45 GHz starting right after July 10, 2016, namely ∼13 months after the estimated onset of the IR outburst. This is the first ever detection of a radio burst associated with an IR accretion outburst from a young stellar object. The flux density at all observed centimetre bands can be reproduced with a simple expanding jet model. At millimetre wavelengths we infer a marginal flux increase with respect to the literature values and we show this is due to free-free emission from the radio jet. Conclusions. Our model fits indicate a significant increase in the jet opening angle and ionized mass loss rate with time. For the first time, we can estimate the ionization fraction in the jet and conclude that this must be low (<14%), lending strong support to the idea that the neutral component is dominant in thermal jets. Our findings strongly suggest that recurrent accretion+ejection episodes may be the main route to the formation of massive stars.

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Section: Centimetre Emissionsupporting

confidence: 65%

Radio outburst from a massive (proto)star

Cesaroni

Moscadelli

Neri

et al. 2018

A&A

Self Cite

102

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“…Because the absorption in the disk wind and the ratio R con are different for optically thick and thin hydrogen lines, the lines of different series can have different shapes or shifts. For example, in the star PV Cep (A5), the ratio R con for Brγ is higher than that for Paβ by about a factor of 7 (Caratti o Garatti et al 2013). Figure 20 illustrates a case when R con for the Brγ line is equal to R 5 (Table 3), and for the Paβ line it is seven times lower.…”

Section: Screening and Extinction Effectsmentioning

confidence: 98%

“…The gas electron temperature T e is assumed to be constant and equal to 10 000 K in all models except B5 and B6; in the latter models T e = 8000 K. The choice of the disk wind parameters is conditioned by the results of the magneto-centrifugal disk wind model for TTSs with some changes in the launching region because of the difference in the inner accretion disk structure (e.g., Natta et al 2001;Dullemond et al 2001). The range of the mass-loss values is based on the estimates of mass loss and accretion rates from the literature (e.g., Hillenbrand et al 1992;Lada & Adams 1992;Hartmann et al 1993;Tambovtseva et al 2001;Muzerolle et al 2004;Garcia Lopez et al 2006;Donehew & Brittain 2011;Klaassen et al 2013;Mendigutía et al 2013).…”

Section: Disk Wind Modelmentioning

confidence: 99%

“…High atomic series lines, in particular, the Brackett series, can be used for these studies (e.g., Garcia Lopez et al 2006;Weigelt et al 2007;Kraus et al 2008;Donehew & Brittain 2010;Caratti o Garatti 2013;Lumsden et al 2012). A comparison of these lines with the Hα lines shows that the latter are often substantially wider than the infrared lines (see, e.g., Hamann & Person 1992;Reipurth et al 1996;Drew et al 1997).…”

Section: Introductionmentioning

confidence: 99%

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Hydrogen lines as a diagnostic tool for studying multicomponent emitting regions in hot young stars: magnetosphere, X-wind, and disk wind

Тамбовцева

Гринин

Weigelt

2014

A&A

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Infrared interferometric observations with high spatial and spectral resolution and their quantitative modeling provide us with a unique opportunity to improve our understanding of the circumstellar environment of young stars and the accretion-ejection process. The goal of this paper is to investigate various models of the emitting regions in young Herbig Ae/Be stars that consist of (i) a compact rotating magnetosphere; (ii) an X-wind; and (iii) a disk wind. These models can be used, for example, to quantitatively interpret line profile measurements and infrared interferometric observations with the AMBER instrument of the Very Large Telescope Interferometer (VLTI) in the high spectral resolution mode (R = 12 000). VLTI/AMBER observations allow us to resolve the disk wind region and study the flux contribution of the unresolved magnetosphere and X-wind region to the total line flux. Analyzing the results of our non-LTE calculations, we conclude that the mechanisms of the different broadening of emission lines of different series include (1) the kinematic expansion due to the motion of the outflowing, accelerating gas in the magneto-centrifugal disk wind; (2) the Stark effect; and (3) the rotation of the magnetosphere. We also investigated extinction effects that can influence the shape of the line profiles. We considered the obscuration of the outer disk wind by an opaque dust and gas disk, the obscuration of the disk wind by a flared disk or by dust in the disk wind itself, and absorption of the star and disk continuum radiation in the disk wind along the line of sight. We show that due to extinction effects, the line profiles can change from double-peaked to single-peaked and P Cygni profiles. We studied the contribution of the different components of the stellar environment to different hydrogen emission lines and investigated how this contribution is dependent on the model parameters. The results of this study can be used for the detailed modeling of the emitting regions of individual young stars.

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“…Hirth et al 1997;Woitas et al 2002;Pyo et al 2003;Coffey et al 2008;Rodríguez-González et al 2012;Caratti o Garatti et al 2013). The nature of the high-velocity jets in many sources has been studied extensively, including searches for signs of jet rotation c 0000 The Authors arXiv:1510.01394v1 [astro-ph.SR] 5 Oct 2015 (Bacciotti et al 2000;Coffey et al 2004Coffey et al , 2007White et al 2014a, hereafter Paper I), recollimation shocks (Paper I; Güdel et al 2005Güdel et al , 2008Günther et al 2009;Bonito et al 2011;Schneider et al 2013) and studies of the propagation of shock-excited moving knots (Paper I; Burrows et al 1996;Reipurth et al 2002;Pyo et al 2003;Agra-Amboage et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Turbulent mixing layers in supersonic protostellar outflows, with application to DG Tauri

White

Bicknell

Sutherland

et al. 2015

Mon. Not. R. Astron. Soc.

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Turbulent entrainment processes may play an important role in the outflows from young stellar objects at all stages of their evolution. In particular, lateral entrainment of ambient material by high-velocity, well-collimated protostellar jets may be the cause of the multiple emission-line velocity components observed in the microjet-scale outflows driven by classical T Tauri stars. Intermediate-velocity outflow components may be emitted by a turbulent, shockexcited mixing layer along the boundaries of the jet. We present a formalism for describing such a mixing layer based on Reynolds decomposition of quantities measuring fundamental properties of the gas. In this model, the molecular wind from large disc radii provides a continual supply of material for entrainment. We calculate the total stress profile in the mixing layer, which allows us to estimate the dissipation of turbulent energy, and hence the luminosity of the layer. We utilize MAPPINGS IV shock models to determine the fraction of total emission that occurs in [Fe II] 1.644 µm line emission in order to facilitate comparison to previous observations of the young stellar object DG Tauri. Our model accurately estimates the luminosity and changes in mass outflow rate of the intermediate-velocity component of the DG Tau approaching outflow. Therefore, we propose that this component represents a turbulent mixing layer surrounding the well-collimated jet in this object. Finally, we compare and contrast our model to previous work in the field.

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LBT/LUCIFER near-infrared spectroscopy of PV Cephei

Cited by 21 publications

References 90 publications

Radio outburst from a massive (proto)star

Radio outburst from a massive (proto)star

Hydrogen lines as a diagnostic tool for studying multicomponent emitting regions in hot young stars: magnetosphere, X-wind, and disk wind

Turbulent mixing layers in supersonic protostellar outflows, with application to DG Tauri

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