Your search keyword '"Wittkowski, Markus"' showing total 81 results

1. A new dimension in the variability of AGB stars: convection patterns size changes with pulsation

Author

Rosales-Guzman, A., Sanchez-Bermudez, J., Paladini, Claudia, Freytag, B., Wittkowski, Markus, Alberdi, A., Baron, Fabien, Berger, J.-P., Chiavassa, Andréa, Höfner, S., Jorissen, Alain, Kervella, Pierre, Le Bouquin, J., Marigo, P., Montargès, Miguel, Trabucchi, M., Tsvetkova, S., Schödel, R., Van Eck, S., Rosales-Guzman, A., Sanchez-Bermudez, J., Paladini, Claudia, Freytag, B., Wittkowski, Markus, Alberdi, A., Baron, Fabien, Berger, J.-P., Chiavassa, Andréa, Höfner, S., Jorissen, Alain, Kervella, Pierre, Le Bouquin, J., Marigo, P., Montargès, Miguel, Trabucchi, M., Tsvetkova, S., Schödel, R., and Van Eck, S.

Abstract

info:eu-repo/semantics/inPress

Published

2024

2. Reconstructing the mid-infrared environment in the stellar merger remnant V838 Monocerotis

Author

Mobeen, Muhammad Zain, Kamiński, Tomasz, Matter, Alexis, Wittkowski, Markus, Monnier, John D., Kraus, Stefan, Bouquin, Jean-Baptiste Le, Anugu, Narsireddy, Brummelaar, Theo Ten, Davies, Claire L., Ennis, Jacob, Gardner, Tyler, Labdon, Aaron, Lanthermann, Cyprien, Schaefer, Gail H., Setterholm, Benjamin R., Ibrahim, Nour, Howell, Steve B., Mobeen, Muhammad Zain, Kamiński, Tomasz, Matter, Alexis, Wittkowski, Markus, Monnier, John D., Kraus, Stefan, Bouquin, Jean-Baptiste Le, Anugu, Narsireddy, Brummelaar, Theo Ten, Davies, Claire L., Ennis, Jacob, Gardner, Tyler, Labdon, Aaron, Lanthermann, Cyprien, Schaefer, Gail H., Setterholm, Benjamin R., Ibrahim, Nour, and Howell, Steve B.

Abstract

V838 Mon is a stellar merger remnant that erupted in 2002 in a luminous red novae event. Although it is well studied in the optical, near infrared and submillimeter regimes, its structure in the mid-infrared wavelengths remains elusive. We observed V838 Mon with the MATISSE (LMN bands) and GRAVITY (K band) instruments at the VLTI and also the MIRCX/MYSTIC (HK bands) instruments at the CHARA array. We geometrically modelled the squared visibilities and the closure phases in each of the bands to obtain constraints on physical parameters. Furthermore, we constructed high resolution images of V838 Mon in the HK bands, using the MIRA and SQUEEZE algorithms to study the immediate surroundings of the star. Lastly, we also modelled the spectral features seen in the K and M bands at various temperatures. The image reconstructions show a bipolar structure that surrounds the central star in the post merger remnant. In the K band, the super resolved images show an extended structure (uniform disk diameter $\sim 1.94$ mas) with a clumpy morphology that is aligned along a north-west position angle (PA) of $-40^\circ$. Whereas in the H band, the extended structure (uniform disk diameter $\sim 1.18$ mas) lies roughly along the same PA. However, the northern lobe is slightly misaligned with respect to the southern lobe, which results in the closure phase deviations. The VLTI and CHARA imaging results show that V838 Mon is surrounded by features that resemble jets that are intrinsically asymmetric. This is also confirmed by the closure phase modelling. Further observations with VLTI can help to determine whether this structure shows any variation over time, and also if such bipolar structures are commonly formed in other stellar merger remnants., Comment: 18 pages, 34 figures

Published

2023

3. The effect of winds in red supergiants: modeling for interferometry

Author

González-Torà, Gemma, Wittkowski, Markus, Davies, Ben, Plez, Bertrand, González-Torà, Gemma, Wittkowski, Markus, Davies, Ben, and Plez, Bertrand

Abstract

Red supergiants (RSGs) are evolved massive stars in a stage preceding core-collapse supernova. Understanding evolved-phases of these cool stars is key to understanding the cosmic matter cycle of our Universe, since they enrich the cosmos with newly formed elements. However, the physical processes that trigger mass loss in their atmospheres are still not fully understood, and remain one of the key questions in stellar astrophysics. We use a new method to study the extended atmospheres of these cold stars, exploring the effect of a stellar wind for both a simple radiative equilibrium model and a semi-empirical model that accounts for a chromospheric temperature structure. We then can compute the intensities, fluxes and visibilities matching the observations for the different instruments at the Very Large Telescope Interferometer (VLTI). Specifically, when comparing with the atmospheric structure of HD 95687 based on published VLTI/AMBER data, we find that our model can accurately match these observations in the Kband, showing the enormous potential of this methodology to reproduce extended atmospheres of RSGs., Comment: 6 pages, 5 figures, to appear at the Proceedings of the IAUS370: Winds of stars and exoplanets. Eds: A. Vidotto and M. Smith-Spanier. Based on a contributed talk on preliminary work from Gonz\'alez-Tor\`a et al., submitted to A&A

Published

2022

4. CHARA/SPICA: a 6-telescope visible instrument for the CHARA Array

Author

Mourard, Denis, Berio, Philippe, Pannetier, Cyril, Nardetto, Nicolas, Allouche, Fatme, Bailet, Christophe, Dejonghe, Julien, Geneslay, Pierre, Jacqmart, Estelle, Lagarde, Stéphane, Lecron, Daniel, Morand, Frédéric, Rousseau, Sylvain, Salabert, David, Spang, Alain, Albrecht, Simon, Anugu, Narsireddy, Bourges, Laurent, Brummelaar, Theo A. ten, Creevey, Orlagh, Deheuvels, Sebastien, de Souza, Armando Domiciano, Gies, Doug, Ligi, Roxanne, Mella, Guillaume, Perraut, Karine, Schaefer, Gail, Wittkowski, Markus, Mourard, Denis, Berio, Philippe, Pannetier, Cyril, Nardetto, Nicolas, Allouche, Fatme, Bailet, Christophe, Dejonghe, Julien, Geneslay, Pierre, Jacqmart, Estelle, Lagarde, Stéphane, Lecron, Daniel, Morand, Frédéric, Rousseau, Sylvain, Salabert, David, Spang, Alain, Albrecht, Simon, Anugu, Narsireddy, Bourges, Laurent, Brummelaar, Theo A. ten, Creevey, Orlagh, Deheuvels, Sebastien, de Souza, Armando Domiciano, Gies, Doug, Ligi, Roxanne, Mella, Guillaume, Perraut, Karine, Schaefer, Gail, and Wittkowski, Markus

Abstract

With a possible angular resolution down to 0.1-0.2 millisecond of arc using the 330 m baselines and the access to the 600-900 nm spectral domain, the CHARA Array is ideally configured for focusing on precise and accurate fundamental parameters of stars. CHARA/SPICA (Stellar Parameters and Images with a Cophased Array) aims at performing a large survey of stars all over the Hertzsprung-Russell diagram. This survey will also study the effects of the different kinds of variability and surface structure on the reliability of the extracted fundamental parameters. New surface-brightness-colour relations will be extracted from this survey, for general purposes on distance determination and the characterization of faint stars. SPICA is made of a visible 6T fibered instrument and of a near-infrared fringe sensor. In this paper, we detail the science program and the main characteristics of SPICA-VIS. We present finally the initial performance obtained during the commissioning.

Published

2022

5. The mid-infrared environment of the stellar merger remnant V838 Monocerotis

Author

Mobeen, Muhammad Zain, Kamiński, Tomasz, Matter, Alexis, Wittkowski, Markus, Paladini, Claudia, Mobeen, Muhammad Zain, Kamiński, Tomasz, Matter, Alexis, Wittkowski, Markus, and Paladini, Claudia

Abstract

In 2002, V838 Monocerotis (V838 Mon) erupted in a red novae event which has been interpreted to be a stellar merger. Soon after reaching peak luminosity, it began to cool, and its spectrum evolved to later spectral types. Dust was also formed in the post-merger remnant, making it bright in the mid-infrared. Interferometric studies at these wavelengths have suggested the presence of a flattened, elongated structure. We investigate, for the first time, the structure and orientation of the dusty envelope surrounding V838 Mon in the $L$(2.8-4.2 $\mu$m) band using recent observations with the MATISSE instrument at the VLTI. We perform simple geometrical modelling of the interferometric observables using basic models (disks, Gaussians, point sources, along with their combinations). We also reconstructed an image and analyzed the corresponding $L$-band spectrum. This study indicates the presence of an elongated, disk-like structure near 3.5$\mu$m, similar to what has been observed in other wavelength regimes. In particular, the orientation at a position angle of -40 degrees agrees with prior measurements in other bands. The dusty elongated structure surrounding V838 Mon appears to be a stable and long lived feature that has been present in the system for over a decade. Its substructure and origin remain unclear, but may be related to mass loss phenomena that took place in the orbital plane of the merged binary., Comment: 9 pages, 11 figures

Published

2021

6. The mid-infrared environment of the stellar merger remnant V838 Monocerotis

Author

Mobeen, Muhammad Zain, Kamiński, Tomasz, Matter, Alexis, Wittkowski, Markus, Paladini, Claudia, Mobeen, Muhammad Zain, Kamiński, Tomasz, Matter, Alexis, Wittkowski, Markus, and Paladini, Claudia

Abstract

In 2002, V838 Monocerotis (V838 Mon) erupted in a red novae event which has been interpreted to be a stellar merger. Soon after reaching peak luminosity, it began to cool, and its spectrum evolved to later spectral types. Dust was also formed in the post-merger remnant, making it bright in the mid-infrared. Interferometric studies at these wavelengths have suggested the presence of a flattened, elongated structure. We investigate, for the first time, the structure and orientation of the dusty envelope surrounding V838 Mon in the $L$(2.8-4.2 $\mu$m) band using recent observations with the MATISSE instrument at the VLTI. We perform simple geometrical modelling of the interferometric observables using basic models (disks, Gaussians, point sources, along with their combinations). We also reconstructed an image and analyzed the corresponding $L$-band spectrum. This study indicates the presence of an elongated, disk-like structure near 3.5$\mu$m, similar to what has been observed in other wavelength regimes. In particular, the orientation at a position angle of -40 degrees agrees with prior measurements in other bands. The dusty elongated structure surrounding V838 Mon appears to be a stable and long lived feature that has been present in the system for over a decade. Its substructure and origin remain unclear, but may be related to mass loss phenomena that took place in the orbital plane of the merged binary., Comment: 9 pages, 11 figures

Published

2021

7. Tomography of cool giant and supergiant star atmospheres: III. Validation of the method on VLTI/AMBER observations of the Mira star S Ori

Author

Kravchenko, K., Wittkowski, Markus, Jorissen, Alain, Chiavassa, Andréa, Van Eck, Sophie, Anderson, Richard R.I., Freytag, Bernd, Käufl, Ulli, Kravchenko, K., Wittkowski, Markus, Jorissen, Alain, Chiavassa, Andréa, Van Eck, Sophie, Anderson, Richard R.I., Freytag, Bernd, and Käufl, Ulli

Abstract

Context. Asymptotic giant branch (AGB) stars are characterized by substantial mass loss, however the mechanism behind it not yet fully understood. The knowledge of the structure and dynamics of AGB-star atmospheres is crucial to better understanding the mass loss. The recently established tomographic method, which relies on the design of spectral masks containing lines that form in given ranges of optical depths in the stellar atmosphere, is an ideal technique for this purpose. Aims. We aim to validate the capability of the tomographic method in probing different geometrical depths in the stellar atmosphere and recovering the relation between optical and geometrical depth scales. Methods. We applied the tomographic method to high-resolution spectro-interferometric VLTI/AMBER observations of the Mira-type AGB star S Ori. The interferometric visibilities were extracted at wavelengths contributing to the tomographic masks and fitted to those computed from a uniform disk model. This allows us to measure the geometrical extent of the atmospheric layer probed by the corresponding mask. We then compared the observed atmospheric extension with others measured from available 1D pulsation CODEX models and 3D radiative-hydrodynamics CO5BOLD simulations. Results. While the average optical depths probed by the tomographic masks in S Ori decrease (with â ¨ log τ0»=-0.45,-1.45, and-2.45 from the innermost to the central and outermost layers), the angular diameters of these layers increase, from 10.59 ± 0.09 mas through 11.84 ± 0.17 mas, up to 14.08 ± 0.15 mas. A similar behavior is observed when the tomographic method is applied to 1D and 3D dynamical models. Conclusions. This study derives, for the first time, a quantitative relation between optical and geometrical depth scales when applied to the Mira star S Ori, or to 1D and 3D dynamical models. In the context of Mira-type stars, knowledge of the link between the optical and geometrical depths opens the way to deriving the shoc, SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2020

8. Tomography of cool giant and supergiant star atmospheres : III. Validation of the method on VLTI/AMBER observations of the Mira star S Ori

Author

Kravchenko, Kateryna, Wittkowski, Markus, Jorissen, Alain, Chiavassa, Andrea, Van Eck, Sophie, Anderson, Richard, I, Freytag, Bernd, Käufl, Ulli, Kravchenko, Kateryna, Wittkowski, Markus, Jorissen, Alain, Chiavassa, Andrea, Van Eck, Sophie, Anderson, Richard, I, Freytag, Bernd, and Käufl, Ulli

Abstract

Context. Asymptotic giant branch (AGB) stars are characterized by substantial mass loss, however the mechanism behind it not yet fully understood. The knowledge of the structure and dynamics of AGB-star atmospheres is crucial to better understanding the mass loss. The recently established tomographic method, which relies on the design of spectral masks containing lines that form in given ranges of optical depths in the stellar atmosphere, is an ideal technique for this purpose.Aims. We aim to validate the capability of the tomographic method in probing different geometrical depths in the stellar atmosphere and recovering the relation between optical and geometrical depth scales.Methods. We applied the tomographic method to high-resolution spectro-interferometric VLTI/AMBER observations of the Mira-type AGB star S Ori. The interferometric visibilities were extracted at wavelengths contributing to the tomographic masks and fitted to those computed from a uniform disk model. This allows us to measure the geometrical extent of the atmospheric layer probed by the corresponding mask. We then compared the observed atmospheric extension with others measured from available 1D pulsation CODEX models and 3D radiative-hydrodynamics CO5BOLD simulations.Results. While the average optical depths probed by the tomographic masks in S Ori decrease (with log tau(0) = -0.45, - 1.45, and - 2.45 from the innermost to the central and outermost layers), the angular diameters of these layers increase, from 10.59 0.09 mas through 11.84 +/- 0.17 mas, up to 14.08 +/- 0.15 mas. A similar behavior is observed when the tomographic method is applied to 1D and 3D dynamical models.Conclusions. This study derives, for the first time, a quantitative relation between optical and geometrical depth scales when applied to the Mira star S Ori, or to 1D and 3D dynamical models. In the context of Mira-type stars, knowledge of the link between the optical and geometrical depths opens the way to deriving the s

Published

2020

9. Tomography of cool giant and supergiant star atmospheres III. Validation of the method on VLTI/AMBER observations of the Mira star S Ori

Author

Kravchenko, Kateryna, Wittkowski, Markus, Jorissen, Alain, Chiavassa, Andrea, Van Eck, Sophie, Anderson, Richard I., Freytag, Bernd, Kaeufl, Ulli, Kravchenko, Kateryna, Wittkowski, Markus, Jorissen, Alain, Chiavassa, Andrea, Van Eck, Sophie, Anderson, Richard I., Freytag, Bernd, and Kaeufl, Ulli

Abstract

The knowledge of the structure and dynamics of AGB-star atmospheres is crucial to better understand the mass loss. The tomographic method, that relies on the design of spectral masks containing lines forming in given ranges of optical depths in the stellar atmosphere, is an ideal technique for this purpose. It is applied to high-resolution spectro-interferometric VLTI/AMBER observations of the Mira-type AGB star S Ori. First, the interferometric visibilities are extracted at wavelengths contributing to the tomographic masks and fitted to those computed from a uniform disk model. This allows the measurement of the geometrical extent of the atmospheric layer probed by the corresponding mask. Then, we compare the observed atmospheric extension with those measured from available 1D pulsation CODEX models and 3D radiative-hydrodynamics CO5BOLD simulations. We found that while the average optical depths probed by the tomographic masks in S Ori decrease (with $<\log \tau_0> = -0.45$, $-1.45$, and $-2.45$ from the innermost to the central and outermost layers), the angular diameters of these layers increase, from 10.59 $\pm$ 0.09 mas through 11.84 $\pm$ 0.17 mas, up to 14.08 $\pm$ 0.15 mas. A similar behavior is observed when the tomographic method is applied to 1D and 3D dynamical models. Thus, this study derives, for the first time, a quantitative relation between optical- and geometrical-depth scales when applied to the Mira star S Ori, or to 1D and 3D dynamical models. In the context of Mira-type stars, the knowledge of the link between the optical and geometrical depths opens the way to derive the shock-wave propagation velocity, which can not be directly observed in these stars., Comment: Accepted for publication in A&A

Published

2020

10. Constraining stellar parameters and atmospheric dynamics of the carbon AGB star V Oph

Author

Rau, Gioia, Ohnaka, Keiichi, Wittkowski, Markus, Airapetian, Vladimir, Carpenter, Kenneth G., Rau, Gioia, Ohnaka, Keiichi, Wittkowski, Markus, Airapetian, Vladimir, and Carpenter, Kenneth G.

Abstract

Molecules and dust produced by the atmospheres of cool evolved stars contribute to a significant amount of the total material found in the interstellar medium. To understand the mechanism behind the mass loss of these stars, it is of pivotal importance to investigate the structure and dynamics of their atmospheres. Our goal is to verify if the extended molecular and dust layers of the carbon-rich asymptotic giant branch (AGB) star V Oph, and their time variations, can be explained by dust-driven winds triggered by stellar pulsation alone, or if other mechanisms are operating. We model V Oph mid-infrared interferometric VLTI-MIDI data ($8$-$13~\mu$m), at phases $0.18$, $0.49$, $0.65$, together with literature photometric data, using the latest-generation self-consistent dynamic atmosphere models for carbon-rich stars: DARWIN. We determine the fundamental stellar parameters: $T_\text{eff} = 2600~$K, $L_\text{bol} = 3585~$L$_{\odot}$, $M = 1.5~$M$_{\odot}$, $C/O = 1.35$, $\dot{M} = 2.50\cdot10^{-6}$M$_{\odot}$/yr. We calculate the stellar photospheric radii at the three phases: $479$, $494$, $448$ R$_{\odot}$; and the dust radii: $780$, $853$, $787$ R$_{\odot}$. The dynamic models can fairly explain the observed $N$-band visibility and spectra, although there is some discrepancy between the data and the models, which is discussed in the text. We discuss the possible causes of the temporal variations of the outer atmosphere, deriving an estimate of the magnetic field strength, and computing upper limits for the Alfv\'{e}n waves velocity. In addition, using period-luminosity sequences, and interferometric modeling, we suggest V Oph as a candidate to be reclassified as a semi-regular star., Comment: Accepted for publication in ApJ. 21 pages, 11 Figures

Published

2019

11. Cool, evolved stars: results, challenges, and promises for the next decade

Author

Rau, Gioia, Montez Jr., Rodolfo, Carpenter, Kenneth G., Wittkowski, Markus, Bladh, Sara, Karovska, Margarita, Airapetian, Vladimir, Ayres, Tom, Boyer, Martha, Chiavassa, Andrea, Clayton, Geoffrey, Danchi, William, De Marco, Orsola, Dupree, Andrea K., Kaminski, Tomasz, Kastner, Joel H., Kerschbaum, Franz, Linsky, Jeffrey, Lopez, Bruno, Monnier, John, Montargès, Miguel, Nielsen, Krister, Ohnaka, Keiichi, Ramstedt, Sofia, Roettenbacher, Rachael, Brummelaar, Theo ten, Paladini, C., Sarangi, Arkaprabha, van Belle, Gerard, Ventura, Paolo, Rau, Gioia, Montez Jr., Rodolfo, Carpenter, Kenneth G., Wittkowski, Markus, Bladh, Sara, Karovska, Margarita, Airapetian, Vladimir, Ayres, Tom, Boyer, Martha, Chiavassa, Andrea, Clayton, Geoffrey, Danchi, William, De Marco, Orsola, Dupree, Andrea K., Kaminski, Tomasz, Kastner, Joel H., Kerschbaum, Franz, Linsky, Jeffrey, Lopez, Bruno, Monnier, John, Montargès, Miguel, Nielsen, Krister, Ohnaka, Keiichi, Ramstedt, Sofia, Roettenbacher, Rachael, Brummelaar, Theo ten, Paladini, C., Sarangi, Arkaprabha, van Belle, Gerard, and Ventura, Paolo

Abstract

Cool, evolved stars are the main source of chemical enrichment of the interstellar medium (ISM), and understanding their mass loss and structure offers a unique opportunity to study the cycle of matter in the Universe. Pulsation, convection, and other dynamic processes in cool evolved stars create an atmosphere where molecules and dust can form, including those necessary to the formation of life (e.g.~Carbon-bearing molecules). Understanding the structure and composition of these stars is thus vital to several aspects of stellar astrophysics, ranging from ISM studies to modeling young galaxies and exoplanet research. Recent modeling efforts and increasingly precise observations now reveal that our understanding of cool stars photospheric, chromospheric, and atmospheric structures is limited by inadequate knowledge of the dynamic and chemical processes at work. Here we outline promising scientific opportunities for the next decade. We identify and discuss the following main opportunities: (1) identify and model the physical processes that must be included in current 1D and 3D atmosphere models of cool, evolved stars; (2) refine our understanding of photospheric, chromospheric, and outer atmospheric regions of cool evolved stars, their properties and parameters, through high-resolution spectroscopic observations, and interferometric observations at high angular resolution; (3) include the neglected role of chromospheric activity in the mass loss process of red giant branch and red super giant stars, and understand the role played by their magnetic fields; (4) identify the important shaping mechanisms for planetary nebulae and their relation with the parent asymptotic giant branch stars., Comment: 10 pages, 2 figures, White Paper submitted to the Astronomy and Astrophysics Decadal Survey (Astro2020)

Published

2019

12. Constraining convection across the AGB with high-angular-resolution observations

Author

Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, Bernd, Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, Jean-Philippe, Siopis, Christos, Mayer, Andreas, Sadowski, Gilles, Kravchenko, K., Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, Ramstedt, Sofia, Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, Bernd, Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, Jean-Philippe, Siopis, Christos, Mayer, Andreas, Sadowski, Gilles, Kravchenko, K., Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, and Ramstedt, Sofia

Abstract

We present very detailed images of the photosphere of an AGB star obtained with the PIONIER instrument, installed at the Very Large Telescope Interferometer (VLTI). The images show a well defined stellar disc populated by a few convective patterns. Thanks to the high precision of the observations we are able to derive the contrast and granulation horizontal scale of the convective pattern for the first time in a direct way. Such quantities are then compared with scaling relations between granule size, effective temperature, and surface gravity that are predicted by simulations of stellar surface convection., SCOPUS: ar.k, info:eu-repo/semantics/published

Published

2019

13. A Realistic Roadmap to Formation Flying Space Interferometry

Author

Monnier, John, Alicia, Aarnio, Absil, Oliver, Anugu, Narsireddy, Baines, Ellyn, Bayo, Amelia, Berger, Jean-Philippe, Cleeves, L. Ilsedore, Dale, Daniel, Danchi, William, de Wit, W. J., Defrère, Denis, Domagal-Goldman, Shawn, Elvis, Martin, Froebrich, Dirk, Gai, Mario, Gandhi, Poshak, Garcia, Paulo, Gardner, Tyler, Gies, Douglas, Gonzalez, Jean-François, Gunter, Brian, Hoenig, Sebastian, Ireland, Michael, Jorgensen, Anders M., Kishimoto, Makoto, Klarmann, Lucia, Kloppenborg, Brian, Kluska, Jacques, Knight, J. Scott, Kral, Quentin, Kraus, Stefan, Labadie, Lucas, Lawson, Peter, LeBouquin, Jean-Baptiste, Leisawitz, David, Lightsey, E.Glenn, Linz, Hendrik, Lipscy, Sarah, MacGregor, Meredith, Matsuo, Hiroshi, Mennesson, Bertrand, Meyer, Michael, Michael, Ernest A., Millour, Florentin, Mozurkewich, David, Norris, Ryan, Ollivier, Marc, Packham, Chris, Petrov, Romain, Pueyo, Laurent, Pope, Benjamin, Quanz, Sascha, Ragland, Sam, Rau, Gioia, Regaly, Zsolt, Riva, Alberto, Roettenbacher, Rachael, Savini, Giorgio, Setterholm, Benjamin, Sewilo, Marta, Smith, Michael, Spencer, Locke, ten Brummelaar, Theo, Turner, Neal, van Belle, Gerard, Weigelt, Gerd, Wittkowski, Markus, Monnier, John, Alicia, Aarnio, Absil, Oliver, Anugu, Narsireddy, Baines, Ellyn, Bayo, Amelia, Berger, Jean-Philippe, Cleeves, L. Ilsedore, Dale, Daniel, Danchi, William, de Wit, W. J., Defrère, Denis, Domagal-Goldman, Shawn, Elvis, Martin, Froebrich, Dirk, Gai, Mario, Gandhi, Poshak, Garcia, Paulo, Gardner, Tyler, Gies, Douglas, Gonzalez, Jean-François, Gunter, Brian, Hoenig, Sebastian, Ireland, Michael, Jorgensen, Anders M., Kishimoto, Makoto, Klarmann, Lucia, Kloppenborg, Brian, Kluska, Jacques, Knight, J. Scott, Kral, Quentin, Kraus, Stefan, Labadie, Lucas, Lawson, Peter, LeBouquin, Jean-Baptiste, Leisawitz, David, Lightsey, E.Glenn, Linz, Hendrik, Lipscy, Sarah, MacGregor, Meredith, Matsuo, Hiroshi, Mennesson, Bertrand, Meyer, Michael, Michael, Ernest A., Millour, Florentin, Mozurkewich, David, Norris, Ryan, Ollivier, Marc, Packham, Chris, Petrov, Romain, Pueyo, Laurent, Pope, Benjamin, Quanz, Sascha, Ragland, Sam, Rau, Gioia, Regaly, Zsolt, Riva, Alberto, Roettenbacher, Rachael, Savini, Giorgio, Setterholm, Benjamin, Sewilo, Marta, Smith, Michael, Spencer, Locke, ten Brummelaar, Theo, Turner, Neal, van Belle, Gerard, Weigelt, Gerd, and Wittkowski, Markus

Abstract

The ultimate astronomical observatory would be a formation flying space interferometer, combining sensitivity and stability with high angular resolution. The smallSat revolution offers a new and maturing prototyping platform for space interferometry and we put forward a realistic plan for achieving first stellar fringes in space by 2030.

Published

2019

14. Constraining convection across the AGB with high-angular-resolution observations

Author

Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, B., Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, J.-P., Siopis, Christos, Mayer, A., Sadowski, Gilles, Kravchenko, Kateryna, Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, Ramstedt, Sofia, Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, B., Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, J.-P., Siopis, Christos, Mayer, A., Sadowski, Gilles, Kravchenko, Kateryna, Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, and Ramstedt, Sofia

Abstract

info:eu-repo/semantics/published

Published

2019

15. Cool, evolved stars: results, challenges, and promises for the next decade

Author

Rau, Gioia, Montez Jr., Rodolfo, Carpenter, Kenneth G., Wittkowski, Markus, Bladh, Sara, Karovska, Margarita, Airapetian, Vladimir, Ayres, Tom, Boyer, Martha, Chiavassa, Andrea, Clayton, Geoffrey, Danchi, William, De Marco, Orsola, Dupree, Andrea K., Kaminski, Tomasz, Kastner, Joel H., Kerschbaum, Franz, Linsky, Jeffrey, Lopez, Bruno, Monnier, John, Montargès, Miguel, Nielsen, Krister, Ohnaka, Keiichi, Ramstedt, Sofia, Roettenbacher, Rachael, Brummelaar, Theo ten, Paladini, C., Sarangi, Arkaprabha, van Belle, Gerard, Ventura, Paolo, Rau, Gioia, Montez Jr., Rodolfo, Carpenter, Kenneth G., Wittkowski, Markus, Bladh, Sara, Karovska, Margarita, Airapetian, Vladimir, Ayres, Tom, Boyer, Martha, Chiavassa, Andrea, Clayton, Geoffrey, Danchi, William, De Marco, Orsola, Dupree, Andrea K., Kaminski, Tomasz, Kastner, Joel H., Kerschbaum, Franz, Linsky, Jeffrey, Lopez, Bruno, Monnier, John, Montargès, Miguel, Nielsen, Krister, Ohnaka, Keiichi, Ramstedt, Sofia, Roettenbacher, Rachael, Brummelaar, Theo ten, Paladini, C., Sarangi, Arkaprabha, van Belle, Gerard, and Ventura, Paolo

Abstract

Cool, evolved stars are the main source of chemical enrichment of the interstellar medium (ISM), and understanding their mass loss and structure offers a unique opportunity to study the cycle of matter in the Universe. Pulsation, convection, and other dynamic processes in cool evolved stars create an atmosphere where molecules and dust can form, including those necessary to the formation of life (e.g.~Carbon-bearing molecules). Understanding the structure and composition of these stars is thus vital to several aspects of stellar astrophysics, ranging from ISM studies to modeling young galaxies and exoplanet research. Recent modeling efforts and increasingly precise observations now reveal that our understanding of cool stars photospheric, chromospheric, and atmospheric structures is limited by inadequate knowledge of the dynamic and chemical processes at work. Here we outline promising scientific opportunities for the next decade. We identify and discuss the following main opportunities: (1) identify and model the physical processes that must be included in current 1D and 3D atmosphere models of cool, evolved stars; (2) refine our understanding of photospheric, chromospheric, and outer atmospheric regions of cool evolved stars, their properties and parameters, through high-resolution spectroscopic observations, and interferometric observations at high angular resolution; (3) include the neglected role of chromospheric activity in the mass loss process of red giant branch and red super giant stars, and understand the role played by their magnetic fields; (4) identify the important shaping mechanisms for planetary nebulae and their relation with the parent asymptotic giant branch stars., Comment: 10 pages, 2 figures, White Paper submitted to the Astronomy and Astrophysics Decadal Survey (Astro2020)

Published

2019

16. Constraining stellar parameters and atmospheric dynamics of the carbon AGB star V Oph

Author

Rau, Gioia, Ohnaka, Keiichi, Wittkowski, Markus, Airapetian, Vladimir, Carpenter, Kenneth G., Rau, Gioia, Ohnaka, Keiichi, Wittkowski, Markus, Airapetian, Vladimir, and Carpenter, Kenneth G.

Abstract

Molecules and dust produced by the atmospheres of cool evolved stars contribute to a significant amount of the total material found in the interstellar medium. To understand the mechanism behind the mass loss of these stars, it is of pivotal importance to investigate the structure and dynamics of their atmospheres. Our goal is to verify if the extended molecular and dust layers of the carbon-rich asymptotic giant branch (AGB) star V Oph, and their time variations, can be explained by dust-driven winds triggered by stellar pulsation alone, or if other mechanisms are operating. We model V Oph mid-infrared interferometric VLTI-MIDI data ($8$-$13~\mu$m), at phases $0.18$, $0.49$, $0.65$, together with literature photometric data, using the latest-generation self-consistent dynamic atmosphere models for carbon-rich stars: DARWIN. We determine the fundamental stellar parameters: $T_\text{eff} = 2600~$K, $L_\text{bol} = 3585~$L$_{\odot}$, $M = 1.5~$M$_{\odot}$, $C/O = 1.35$, $\dot{M} = 2.50\cdot10^{-6}$M$_{\odot}$/yr. We calculate the stellar photospheric radii at the three phases: $479$, $494$, $448$ R$_{\odot}$; and the dust radii: $780$, $853$, $787$ R$_{\odot}$. The dynamic models can fairly explain the observed $N$-band visibility and spectra, although there is some discrepancy between the data and the models, which is discussed in the text. We discuss the possible causes of the temporal variations of the outer atmosphere, deriving an estimate of the magnetic field strength, and computing upper limits for the Alfv\'{e}n waves velocity. In addition, using period-luminosity sequences, and interferometric modeling, we suggest V Oph as a candidate to be reclassified as a semi-regular star., Comment: Accepted for publication in ApJ. 21 pages, 11 Figures

Published

2019

17. Tomography of evolved star atmospheres

Author

Van Eck, Sophie, Chiavassa, Andréa, Jorissen, Alain, Godefroid, Michel, Perrin, Guy, Wittkowski, Markus, Freytag, Bernd, Kravchenko, Kateryna, Van Eck, Sophie, Chiavassa, Andréa, Jorissen, Alain, Godefroid, Michel, Perrin, Guy, Wittkowski, Markus, Freytag, Bernd, and Kravchenko, Kateryna

Abstract

Cool giant and supergiant stars are among the largest and most luminous stars in the Universe and, therefore, dominate the integrated light of their host galaxies. These stars were extensively studied during last few decades, however their relevant properties like photometric variability and mass loss are still poorly constrained. Understanding of these properties is crucial in the context of a broad range of astrophysical questions including chemical enrichment of the Universe, supernova progenitors, and the extragalactic distance scale. Atmospheres of giant and supergiant stars are characterized by complex dynamics due to different interacting processes, such as convection, pulsation, formation of molecules and dust, and the development of mass loss. Current 1D/3D dynamical model atmospeheres are able to simulate these processes and produce a good agreement with the observed spectral features of evolved stars. However, the models lack constraints and need to be confronted to observables. Dynamical processes in stellar atmospheres impact the formation of spectral lines producing their asymmetries and Doppler shifts. Thus, by studying the line-profile variations on spatial and temporal scales it is possible to reconstruct atmospheric motions in evolved stars. As will be shown in this thesis, a tomographic method is an ideal technique for this purpose. The tomographic method is based on construction and cross-correlation of spectral templates (masks) with observed or synthetic stellar spectra in order to recover velocity fields at different optical depths in the stellar atmosphere.The first part of the thesis further improves the original implementation of the tomographic method. This improvement involves the computation of the contribution function in order to correctly determine an optical depth of formation of spectral lines. The tomographic method is, then, fully validated by applying it to a stellar convection simulation of a red supergiant star and correctly re, Doctorat en Sciences, info:eu-repo/semantics/nonPublished

Published

2019

18. Multiple Star Systems in the Orion Nebula

Author

GRAVITY collaboration, Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, António, Anugu, Narsireddy, Ávila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Bland, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti o, Chapron, Frédéric, Clénet, Yann, Collin, Claude, Foresto, Vincent Coudé du, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Ströbele, Françoise, Dembet, Roderick, Derie, Frédéric, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fédou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gandron, Éric, Gillessen, Stefan, Gonté, Frédéric, Gordo, Paulo, Grözinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haußmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Hummel, Christian A., Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kandrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Köhler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrère, Vincent, Lazareff, Bernard, Bouquin, Jean-Baptiste Le, Léna, Pierre, Lenzen, Rainer, Lévêque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Mérand, Antoine, Moulin, Thibaut, Müller, Eric, Müller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflüger, Andreas, Duc, Thanh Phan, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramírez, Andrés, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodríguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gérard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schöller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frédéric, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, Zins, Gérard, GRAVITY collaboration, Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, António, Anugu, Narsireddy, Ávila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Bland, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti o, Chapron, Frédéric, Clénet, Yann, Collin, Claude, Foresto, Vincent Coudé du, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Ströbele, Françoise, Dembet, Roderick, Derie, Frédéric, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fédou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gandron, Éric, Gillessen, Stefan, Gonté, Frédéric, Gordo, Paulo, Grözinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haußmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Hummel, Christian A., Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kandrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Köhler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrère, Vincent, Lazareff, Bernard, Bouquin, Jean-Baptiste Le, Léna, Pierre, Lenzen, Rainer, Lévêque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Mérand, Antoine, Moulin, Thibaut, Müller, Eric, Müller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflüger, Andreas, Duc, Thanh Phan, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramírez, Andrés, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodríguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gérard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schöller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frédéric, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, and Zins, Gérard

Abstract

This work presents an interferometric study of the massive-binary fraction in the Orion Trapezium Cluster with the recently comissioned GRAVITY instrument. We observe a total of 16 stars of mainly OB spectral type. We find three previously unknown companions for $\theta ^1$ Ori B, $\theta ^2$ Ori B, and $\theta ^2$ Ori C. We determine a separation for the previously suspected companion of NU Ori. We confirm four companions for $\theta ^1$ Ori A, $\theta ^1$ Ori C, $\theta ^1$ Ori D, and $\theta ^2$ Ori A, all with substantially improved astrometry and photometric mass estimates. We refine the orbit of the eccentric high-mass binary $\theta ^1$ Ori C and we are able to derive a new orbit for $\theta ^1$ Ori D. We find a system mass of 21.7 $M_{\odot}$ and a period of $53$ days. Together with other previously detected companions seen in spectroscopy or direct imaging, eleven of the 16 high-mass stars are multiple systems. We obtain a total number of 22 companions with separations up to 600 AU. The companion fraction of the early B and O stars in our sample is about 2, significantly higher than in earlier studies of mostly OB associations. The separation distribution hints towards a bimodality. Such a bimodality has been previously found in A stars, but rarely in OB binaries, which up to this point have been assumed to be mostly compact with a tail of wider companions. We also do not find a substantial population of equal-mass binaries. The observed distribution of mass ratios declines steeply with mass, and like the direct star counts, indicates that our companions follow a standard power law initial mass function. Again, this is in contrast to earlier findings of flat mass ratio distributions in OB associations. We exclude collision as a dominant formation mechanism but find no clear preference for core accretion or competitive accretion., Comment: Accepted for publication in A&A

Published

2018

19. Multiple star systems in the Orion nebula

Author

Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, Antonio, Anugu, Narsireddy, Avila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Blind, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti O., Chapron, Frederic, Clenet, Yann, Collin, Claude, du Foresto, Vincent Coude, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Stroebele, Francoise, Dembet, Roderick, Derie, Frederic, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fedou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gendron, Eric, Gillessen, Stefan, Gonte, Frederic, Gordo, Paulo, Groezinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haussmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kendrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Koehler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrere, Vincent, Lazareff, Bernard, Le Bouquin, Jean-Baptiste, Lena, Pierre, Lenzen, Rainer, Leveque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Merand, Antoine, Moulin, Thibaut, Mueller, Eric, Mueller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflueger, Andreas, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramirez, Andres, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodriguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gerard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schoeller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frederic, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, Zins, Gerard, Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, Antonio, Anugu, Narsireddy, Avila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Blind, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti O., Chapron, Frederic, Clenet, Yann, Collin, Claude, du Foresto, Vincent Coude, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Stroebele, Francoise, Dembet, Roderick, Derie, Frederic, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fedou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gendron, Eric, Gillessen, Stefan, Gonte, Frederic, Gordo, Paulo, Groezinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haussmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kendrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Koehler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrere, Vincent, Lazareff, Bernard, Le Bouquin, Jean-Baptiste, Lena, Pierre, Lenzen, Rainer, Leveque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Merand, Antoine, Moulin, Thibaut, Mueller, Eric, Mueller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflueger, Andreas, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramirez, Andres, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodriguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gerard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schoeller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frederic, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, and Zins, Gerard

Abstract

This work presents an interferometric study of the massive-binary fraction in the Orion Trapezium cluster with the recently comissioned GRAVITY instrument. We observed a total of 16 stars of mainly OB spectral type. We find three previously unknown companions for theta(1) Ori B, theta(2) Ori B, and theta(2) Ori C. We determined a separation for the previously suspected companion of NU Ori. We confirm four companions for theta(1) Ori A, theta(1) Ori C, theta(1) Ori D, and theta(2) Ori A, all with substantially improved astrometry and photometric mass estimates. We refined the orbit of the eccentric high-mass binary theta(1) Ori C and we are able to derive a new orbit for theta(1) Ori D. We find a system mass of 21.7 M-circle dot and a period of 53 days. Together with other previously detected companions seen in spectroscopy or direct imaging, eleven of the 16 high-mass stars are multiple systems. We obtain a total number of 22 companions with separations up to 600 AU. The companion fraction of the early B and O stars in our sample is about two, significantly higher than in earlier studies of mostly OB associations. The separation distribution hints toward a bimodality. Such a bimodality has been previously found in A stars, but rarely in OB binaries, which up to this point have been assumed to be mostly compact with a tail of wider companions. We also do not find a substantial population of equal-mass binaries. The observed distribution of mass ratios declines steeply with mass, and like the direct star counts, indicates that our companions follow a standard power law initial mass function. Again, this is in contrast to earlier findings of flat mass ratio distributions in OB associations. We excluded collision as a dominant formation mechanism but find no clear preference for core accretion or competitive accretion.

Published

2018

20. Multiple star systems in the Orion nebula

Author

Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, Antonio, Anugu, Narsireddy, Avila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Blind, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti O., Chapron, Frederic, Clenet, Yann, Collin, Claude, du Foresto, Vincent Coude, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Stroebele, Francoise, Dembet, Roderick, Derie, Frederic, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fedou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gendron, Eric, Gillessen, Stefan, Gonte, Frederic, Gordo, Paulo, Groezinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haussmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kendrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Koehler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrere, Vincent, Lazareff, Bernard, Le Bouquin, Jean-Baptiste, Lena, Pierre, Lenzen, Rainer, Leveque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Merand, Antoine, Moulin, Thibaut, Mueller, Eric, Mueller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflueger, Andreas, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramirez, Andres, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodriguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gerard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schoeller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frederic, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, Zins, Gerard, Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, Antonio, Anugu, Narsireddy, Avila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Blind, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti O., Chapron, Frederic, Clenet, Yann, Collin, Claude, du Foresto, Vincent Coude, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Stroebele, Francoise, Dembet, Roderick, Derie, Frederic, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fedou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gendron, Eric, Gillessen, Stefan, Gonte, Frederic, Gordo, Paulo, Groezinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haussmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kendrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Koehler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrere, Vincent, Lazareff, Bernard, Le Bouquin, Jean-Baptiste, Lena, Pierre, Lenzen, Rainer, Leveque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Merand, Antoine, Moulin, Thibaut, Mueller, Eric, Mueller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflueger, Andreas, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramirez, Andres, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodriguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gerard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schoeller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frederic, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, and Zins, Gerard

Abstract

This work presents an interferometric study of the massive-binary fraction in the Orion Trapezium cluster with the recently comissioned GRAVITY instrument. We observed a total of 16 stars of mainly OB spectral type. We find three previously unknown companions for theta(1) Ori B, theta(2) Ori B, and theta(2) Ori C. We determined a separation for the previously suspected companion of NU Ori. We confirm four companions for theta(1) Ori A, theta(1) Ori C, theta(1) Ori D, and theta(2) Ori A, all with substantially improved astrometry and photometric mass estimates. We refined the orbit of the eccentric high-mass binary theta(1) Ori C and we are able to derive a new orbit for theta(1) Ori D. We find a system mass of 21.7 M-circle dot and a period of 53 days. Together with other previously detected companions seen in spectroscopy or direct imaging, eleven of the 16 high-mass stars are multiple systems. We obtain a total number of 22 companions with separations up to 600 AU. The companion fraction of the early B and O stars in our sample is about two, significantly higher than in earlier studies of mostly OB associations. The separation distribution hints toward a bimodality. Such a bimodality has been previously found in A stars, but rarely in OB binaries, which up to this point have been assumed to be mostly compact with a tail of wider companions. We also do not find a substantial population of equal-mass binaries. The observed distribution of mass ratios declines steeply with mass, and like the direct star counts, indicates that our companions follow a standard power law initial mass function. Again, this is in contrast to earlier findings of flat mass ratio distributions in OB associations. We excluded collision as a dominant formation mechanism but find no clear preference for core accretion or competitive accretion.

Published

2018

21. Multiple Star Systems in the Orion Nebula

Author

GRAVITY collaboration, Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, António, Anugu, Narsireddy, Ávila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Bland, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti o, Chapron, Frédéric, Clénet, Yann, Collin, Claude, Foresto, Vincent Coudé du, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Ströbele, Françoise, Dembet, Roderick, Derie, Frédéric, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fédou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gandron, Éric, Gillessen, Stefan, Gonté, Frédéric, Gordo, Paulo, Grözinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haußmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Hummel, Christian A., Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kandrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Köhler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrère, Vincent, Lazareff, Bernard, Bouquin, Jean-Baptiste Le, Léna, Pierre, Lenzen, Rainer, Lévêque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Mérand, Antoine, Moulin, Thibaut, Müller, Eric, Müller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflüger, Andreas, Duc, Thanh Phan, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramírez, Andrés, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodríguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gérard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schöller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frédéric, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, Zins, Gérard, GRAVITY collaboration, Karl, Martina, Pfuhl, Oliver, Eisenhauer, Frank, Genzel, Reinhard, Grellmann, Rebekka, Habibi, Maryam, Abuter, Roberto, Accardo, Matteo, Amorim, António, Anugu, Narsireddy, Ávila, Gerardo, Benisty, Myriam, Berger, Jean-Philippe, Bland, Nicolas, Bonnet, Henri, Bourget, Pierre, Brandner, Wolfgang, Brast, Roland, Buron, Alexander, Garatti, Alessio Caratti o, Chapron, Frédéric, Clénet, Yann, Collin, Claude, Foresto, Vincent Coudé du, de Wit, Willem-Jan, de Zeeuw, Tim, Deen, Casey, Delplancke-Ströbele, Françoise, Dembet, Roderick, Derie, Frédéric, Dexter, Jason, Duvert, Gilles, Ebert, Monica, Eckart, Andreas, Esselborn, Michael, Fédou, Pierre, Finger, Gert, Garcia, Paulo, Dabo, Cesar Enrique Garcia, Lopez, Rebeca Garcia, Gao, Feng, Gandron, Éric, Gillessen, Stefan, Gonté, Frédéric, Gordo, Paulo, Grözinger, Ulrich, Guajardo, Patricia, Guieu, Sylvain, Haguenauer, Pierre, Hans, Oliver, Haubois, Xavier, Haug, Marcus, Haußmann, Frank, Henning, Thomas, Hippler, Stefan, Horrobin, Matthew, Huber, Armin, Hubert, Zoltan, Hubin, Norbert, Hummel, Christian A., Jakob, Gerd, Jochum, Lieselotte, Jocou, Laurent, Kaufer, Andreas, Kellner, Stefan, Kandrew, Sarah, Kern, Lothar, Kervella, Pierre, Kiekebusch, Mario, Klein, Ralf, Köhler, Rainer, Kolb, Johan, Kulas, Martin, Lacour, Sylvestre, Lapeyrère, Vincent, Lazareff, Bernard, Bouquin, Jean-Baptiste Le, Léna, Pierre, Lenzen, Rainer, Lévêque, Samuel, Lin, Chien-Cheng, Lippa, Magdalena, Magnard, Yves, Mehrgan, Leander, Mérand, Antoine, Moulin, Thibaut, Müller, Eric, Müller, Friedrich, Neumann, Udo, Oberti, Sylvain, Ott, Thomas, Pallanca, Laurent, Panduro, Johana, Pasquini, Luca, Paumard, Thibaut, Percheron, Isabelle, Perraut, Karine, Perrin, Guy, Pflüger, Andreas, Duc, Thanh Phan, Plewa, Philipp M., Popovic, Dan, Rabien, Sebastian, Ramírez, Andrés, Ramos, Jose, Rau, Christian, Riquelme, Miguel, Rodríguez-Coira, Gustavo, Rohloff, Ralf-Rainer, Rosales, Alejandra, Rousset, Gérard, Sanchez-Bermudez, Joel, Scheithauer, Silvia, Schöller, Markus, Schuhler, Nicolas, Spyromilio, Jason, Straub, Odele, Straubmeier, Christian, Sturm, Eckhard, Suarez, Marcos, Tristram, Konrad R. W., Ventura, Noel, Vincent, Frédéric, Waisberg, Idel, Wank, Imke, Widmann, Felix, Wieprecht, Ekkehard, Wiest, Michael, Wiezorrek, Erich, Wittkowski, Markus, Woillez, Julien, Wolff, Burkhard, Yazici, Senol, Ziegler, Denis, and Zins, Gérard

Abstract

This work presents an interferometric study of the massive-binary fraction in the Orion Trapezium Cluster with the recently comissioned GRAVITY instrument. We observe a total of 16 stars of mainly OB spectral type. We find three previously unknown companions for $\theta ^1$ Ori B, $\theta ^2$ Ori B, and $\theta ^2$ Ori C. We determine a separation for the previously suspected companion of NU Ori. We confirm four companions for $\theta ^1$ Ori A, $\theta ^1$ Ori C, $\theta ^1$ Ori D, and $\theta ^2$ Ori A, all with substantially improved astrometry and photometric mass estimates. We refine the orbit of the eccentric high-mass binary $\theta ^1$ Ori C and we are able to derive a new orbit for $\theta ^1$ Ori D. We find a system mass of 21.7 $M_{\odot}$ and a period of $53$ days. Together with other previously detected companions seen in spectroscopy or direct imaging, eleven of the 16 high-mass stars are multiple systems. We obtain a total number of 22 companions with separations up to 600 AU. The companion fraction of the early B and O stars in our sample is about 2, significantly higher than in earlier studies of mostly OB associations. The separation distribution hints towards a bimodality. Such a bimodality has been previously found in A stars, but rarely in OB binaries, which up to this point have been assumed to be mostly compact with a tail of wider companions. We also do not find a substantial population of equal-mass binaries. The observed distribution of mass ratios declines steeply with mass, and like the direct star counts, indicates that our companions follow a standard power law initial mass function. Again, this is in contrast to earlier findings of flat mass ratio distributions in OB associations. We exclude collision as a dominant formation mechanism but find no clear preference for core accretion or competitive accretion., Comment: Accepted for publication in A&A

Published

2018

22. Constraining Convection in Evolved Stars with the VLTI

Author

Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, Bernd, Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, Jean-Philippe, Siopis, Christos, Mayer, Andreas, Sadowski, Gilles, Kravchenko, Kateryna, Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, Ramstedt, Sofia, Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, Bernd, Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, Jean-Philippe, Siopis, Christos, Mayer, Andreas, Sadowski, Gilles, Kravchenko, Kateryna, Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, and Ramstedt, Sofia

Abstract

info:eu-repo/semantics/published

Published

2018

23. The VLTI/MIDI view on the inner mass loss of evolved stars from the Herschel MESS sample

Author

Paladini, Claudia, Klotz, Daniela, Sacuto, Stéphane, Lagadec, Eric, Wittkowski, Markus, Hron, Josef, Jorissen, Alain, Groenewegen, Martin A. T., Kerschbaum, Franz, Verhoelst, T., Rau, Gioia, Olofsson, Hans, Zhao-Geisler, Ronny, Matter, A., Paladini, Claudia, Klotz, Daniela, Sacuto, Stéphane, Lagadec, Eric, Wittkowski, Markus, Hron, Josef, Jorissen, Alain, Groenewegen, Martin A. T., Kerschbaum, Franz, Verhoelst, T., Rau, Gioia, Olofsson, Hans, Zhao-Geisler, Ronny, and Matter, A.

Abstract

Context. The mass-loss process from evolved stars is a key ingredient for our understanding of many fields of astrophysics, including stellar evolution and the chemical enrichment of the interstellar medium (ISM) via stellar yields. Nevertheless, many questions are still unsolved, one of which is the geometry of the mass-loss process. Aims. Taking advantage of the results from the Herschel Mass loss of Evolved StarS (MESS) programme, we initiated a coordinated effort to characterise the geometry of mass loss from evolved red giants at various spatial scales. Methods. For this purpose we used the MID-infrared interferometric Instrument (MIDI) to resolve the inner envelope of 14 asymptotic giant branch stars (AGBs) in the MESS sample. In this contribution we present an overview of the interferometric data collected within the frame of our Large Programme, and we also add archive data for completeness. We studied the geometry of the inner atmosphere by comparing the observations with predictions from different geometric models. Results. Asymmetries are detected for the following five stars: R Leo, RT Vir, π1Gruis, omi Ori, and R Crt. All the objects are O-rich or S-type, suggesting that asymmetries in the N band are more common among stars with such chemistry. We speculate that this fact is related to the characteristics of the dust grains. Except for one star, no interferometric variability is detected, i.e. the changes in size of the shells of non-mira stars correspond to changes of the visibility of less than 10%. The observed spectral variability confirms previous findings from the literature. The detection of dust in our sample follows the location of the AGBs in the IRAS colour-colour diagram: More dust is detected around oxygen-rich stars in region II and in the carbon stars in region VII. The SiC dust feature does not appear in the visibility spectrum of the U Ant and S Sct, which are two carbon stars with detached shells. This finding has implications for the, SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2017

24. Large granulation cells on the surface of the giant star pi 1 Gruis.

Author

Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, Bernd, Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, Jean-Philippe, Siopis, Christos, Mayer, A., Sadowski, Gilles, Kravchenko, Kateryna, Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, Ramstedt, Sofia, Paladini, Claudia, Baron, Fabien, Jorissen, Alain, Le Bouquin, Jean Baptiste, Freytag, Bernd, Van Eck, Sophie, Wittkowski, Markus, Hron, Josef, Chiavassa, Andréa, Berger, Jean-Philippe, Siopis, Christos, Mayer, A., Sadowski, Gilles, Kravchenko, Kateryna, Shetye, Shreeya, Kerschbaum, Franz, Kluska, Jacques, and Ramstedt, Sofia

Abstract

Convection plays a major part in many astrophysical processes, including energy transport, pulsation, dynamos and winds on evolved stars, in dust clouds and on brown dwarfs. Most of our knowledge about stellar convection has come from studying the Sun: about two million convective cells with typical sizes of around 2,000 kilometres across are present on the surface of the Sun-a phenomenon known as granulation. But on the surfaces of giant and supergiant stars there should be only a few large (several tens of thousands of times larger than those on the Sun) convective cells, owing to low surface gravity. Deriving the characteristic properties of convection (such as granule size and contrast) for the most evolved giant and supergiant stars is challenging because their photospheres are obscured by dust, which partially masks the convective patterns. These properties can be inferred from geometric model fitting, but this indirect method does not provide information about the physical origin of the convective cells. Here we report interferometric images of the surface of the evolved giant star π1 Gruis, of spectral type S5,7. Our images show a nearly circular, dust-free atmosphere, which is very compact and only weakly affected by molecular opacity. We find that the stellar surface has a complex convective pattern with an average intensity contrast of 12 per cent, which increases towards shorter wavelengths. We derive a characteristic horizontal granule size of about 1.2 × 1011 metres, which corresponds to 27 per cent of the diameter of the star. Our measurements fall along the scaling relations between granule size, effective temperature and surface gravity that are predicted by simulations of stellar surface convection., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2017

25. The extended molecular envelope of the asymptotic giant branch star π 1 Gruis as seen by ALMA: I. Large-scale kinematic structure and CO excitation properties

Author

Doan, L., Paladini, Claudia, Wittkowski, Markus, Ramstedt, Sofia, Vlemmings, Wouter H.T., Höfner, Susanne, De Beck, E., Kerschbaum, Franz, Lindqvist, Michael, Maercker, Matthias, Mohamed, Shazrene, Doan, L., Paladini, Claudia, Wittkowski, Markus, Ramstedt, Sofia, Vlemmings, Wouter H.T., Höfner, Susanne, De Beck, E., Kerschbaum, Franz, Lindqvist, Michael, Maercker, Matthias, and Mohamed, Shazrene

Abstract

Context. The S-type asymptotic giant branch (AGB) star π1 Gru has a known companion at a separation of 2′ 7 (≈ 400 AU). Previous observations of the circumstellar envelope (CSE) show strong deviations from spherical symmetry. The envelope structure, including an equatorial torus and a fast bipolar outflow, is rarely seen in the AGB phase and is particularly unexpected in such a wide binary system. Therefore a second, closer companion has been suggested, but the evidence is not conclusive. Aims. The aim is to make a 3D model of the CSE and to constrain the density and temperature distribution using new spatially resolved observations of the CO rotational lines. Methods. We have observed the J = 3-2 line emission from 12CO and 13CO using the compact arrays of the Atacama Large Millimeter/submillimeter Array (ALMA). The new ALMA data, together with previously published 12CO J = 2-1 data from the Submillimeter Array (SMA), and the 12CO J = 5-4 and J = 9-8 lines observed with Herschel/Heterodyne Instrument for the Far-Infrared (HIFI), is modeled with the 3D non-LTE radiative transfer code SHAPEMOL. Results. The data analysis clearly confirms the torus-bipolar structure. The 3D model of the CSE that satisfactorily reproduces the data consists of three kinematic components: a radially expanding torus with velocity slowly increasing from 8 to 13 km s-1 along the equator plane; a radially expanding component at the center with a constant velocity of 14 km s-1; and a fast, bipolar outflow with velocity proportionally increasing from 14 km s-1 at the base up to 100 km s-1 at the tip, following a linear radial dependence. The results are used to estimate an average mass-loss rate during the creation of the torus of 7.7 × 10-7 M⊙ yr-1. The total mass and linear momentum of the fast outflow are estimated at 7.3 × 10-4 M⊙ and 9.6 × 1037 g cm s-1, respectively. The momentum of the outflow is in excess (by a factor of about 20) of what could be generated by radiation pressure alone, SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2017

26. Science cases for a visible interferometer

Author

Stee, Philippe, Allard, France, Benisty, Myriam, Bigot, Lionel, Blind, Nicolas, Boffin, Henri, Fernandes, Marcelo Borges, Carciofi, Alex, Chiavassa, Andrea, Creevey, Orlagh, Cruzalebes, Pierre, de Wit, Willem-Jan, de Souza, Armando Domiciano, Elvis, Martin, Fabas, Nicolas, Faes, Daniel, Gallenne, Alexandre, Pena, Carlos Guerrero, Hillen, Michel, Hoenig, Sebastian, Ireland, Michael, Kervella, Pierre, Kishimoto, Makoto, Kostogryz, Nadia, Kraus, Stefan, Labeyrie, Antoine, Bouquin, Jean-Baptiste Le, Lebre, Agnès, Ligi, Roxanne, Marconi, Alessandro, Marsh, Thomas, Meilland, Anthony, Millour, Florentin, Monnier, John, Mourard, Denis, Nardetto, Nicolas, Ohnaka, Keiichi, Paladini, Claudia, Perraut, Karine, Perrin, Guy, Petit, Pascal, Petrov, Romain, Rakshit, Suvendu, Schaefer, Gail, Schneider, Jean, Shulyak, Denis, Simon, Michal, Soulez, Ferreol, Steeghs, Danny, Tallon-Bosc, Isabelle, Tallon, Michel, Brummelaar, Theo ten, Thiebaut, Eric, Thévenin, Frédéric, Van Winckel, Hans, Wittkowski, Markus, Zorec, Juan, Stee, Philippe, Allard, France, Benisty, Myriam, Bigot, Lionel, Blind, Nicolas, Boffin, Henri, Fernandes, Marcelo Borges, Carciofi, Alex, Chiavassa, Andrea, Creevey, Orlagh, Cruzalebes, Pierre, de Wit, Willem-Jan, de Souza, Armando Domiciano, Elvis, Martin, Fabas, Nicolas, Faes, Daniel, Gallenne, Alexandre, Pena, Carlos Guerrero, Hillen, Michel, Hoenig, Sebastian, Ireland, Michael, Kervella, Pierre, Kishimoto, Makoto, Kostogryz, Nadia, Kraus, Stefan, Labeyrie, Antoine, Bouquin, Jean-Baptiste Le, Lebre, Agnès, Ligi, Roxanne, Marconi, Alessandro, Marsh, Thomas, Meilland, Anthony, Millour, Florentin, Monnier, John, Mourard, Denis, Nardetto, Nicolas, Ohnaka, Keiichi, Paladini, Claudia, Perraut, Karine, Perrin, Guy, Petit, Pascal, Petrov, Romain, Rakshit, Suvendu, Schaefer, Gail, Schneider, Jean, Shulyak, Denis, Simon, Michal, Soulez, Ferreol, Steeghs, Danny, Tallon-Bosc, Isabelle, Tallon, Michel, Brummelaar, Theo ten, Thiebaut, Eric, Thévenin, Frédéric, Van Winckel, Hans, Wittkowski, Markus, and Zorec, Juan

Abstract

High spatial resolution is the key for the understanding various astrophysical phenomena. But even with the future E-ELT, single dish instruments are limited to a spatial resolution of about 4 mas in the visible. For the closest objects within our Galaxy most of the stellar photosphere remains smaller than 1 mas. With the success of long baseline interferometry these limitations were soom overcome. Today low and high resolution interferometric instruments on the VLTI and CHARA offer an immense range of astrophysical studies. Combining more telescopes and moving to visible wavelengths broadens the science cases even more. With the idea of developing strong science cases for a future visible interferometer, we organized a science group around the following topics: pre-main sequence and main sequence stars, fundamental parameters, asteroseismology and classical pulsating stars, evolved stars, massive stars, active galactic nuclei (AGNs) and imaging techniques. A meeting was organized on the 15th and 16th of January, 2015 in Nice with the support of the Action Specific in Haute Resolution Angulaire (ASHRA), the Programme National en Physique Stellaire (PNPS), the Lagrange Laboratory and the Observatoire de la Cote d'Azur, in order to present these cases and to discuss them further for future visible interferometers. This White Paper presents the outcome of the exchanges. This book is dedicated to the memory of our colleague Olivier Chesneau who passed away at the age of 41., Comment: White Paper prospective. This book is dedicated to the memory of our colleague Olivier Chesneau who passed away at the age of 41. v2 includes some corrections to text

Published

2017

27. Science cases for a visible interferometer

Author

Stee, Philippe, Allard, France, Benisty, Myriam, Bigot, Lionel, Blind, Nicolas, Boffin, Henri, Fernandes, Marcelo Borges, Carciofi, Alex, Chiavassa, Andrea, Creevey, Orlagh, Cruzalebes, Pierre, de Wit, Willem-Jan, de Souza, Armando Domiciano, Elvis, Martin, Fabas, Nicolas, Faes, Daniel, Gallenne, Alexandre, Pena, Carlos Guerrero, Hillen, Michel, Hoenig, Sebastian, Ireland, Michael, Kervella, Pierre, Kishimoto, Makoto, Kostogryz, Nadia, Kraus, Stefan, Labeyrie, Antoine, Bouquin, Jean-Baptiste Le, Lebre, Agnès, Ligi, Roxanne, Marconi, Alessandro, Marsh, Thomas, Meilland, Anthony, Millour, Florentin, Monnier, John, Mourard, Denis, Nardetto, Nicolas, Ohnaka, Keiichi, Paladini, Claudia, Perraut, Karine, Perrin, Guy, Petit, Pascal, Petrov, Romain, Rakshit, Suvendu, Schaefer, Gail, Schneider, Jean, Shulyak, Denis, Simon, Michal, Soulez, Ferreol, Steeghs, Danny, Tallon-Bosc, Isabelle, Tallon, Michel, Brummelaar, Theo ten, Thiebaut, Eric, Thévenin, Frédéric, Van Winckel, Hans, Wittkowski, Markus, Zorec, Juan, Stee, Philippe, Allard, France, Benisty, Myriam, Bigot, Lionel, Blind, Nicolas, Boffin, Henri, Fernandes, Marcelo Borges, Carciofi, Alex, Chiavassa, Andrea, Creevey, Orlagh, Cruzalebes, Pierre, de Wit, Willem-Jan, de Souza, Armando Domiciano, Elvis, Martin, Fabas, Nicolas, Faes, Daniel, Gallenne, Alexandre, Pena, Carlos Guerrero, Hillen, Michel, Hoenig, Sebastian, Ireland, Michael, Kervella, Pierre, Kishimoto, Makoto, Kostogryz, Nadia, Kraus, Stefan, Labeyrie, Antoine, Bouquin, Jean-Baptiste Le, Lebre, Agnès, Ligi, Roxanne, Marconi, Alessandro, Marsh, Thomas, Meilland, Anthony, Millour, Florentin, Monnier, John, Mourard, Denis, Nardetto, Nicolas, Ohnaka, Keiichi, Paladini, Claudia, Perraut, Karine, Perrin, Guy, Petit, Pascal, Petrov, Romain, Rakshit, Suvendu, Schaefer, Gail, Schneider, Jean, Shulyak, Denis, Simon, Michal, Soulez, Ferreol, Steeghs, Danny, Tallon-Bosc, Isabelle, Tallon, Michel, Brummelaar, Theo ten, Thiebaut, Eric, Thévenin, Frédéric, Van Winckel, Hans, Wittkowski, Markus, and Zorec, Juan

Abstract

High spatial resolution is the key for the understanding various astrophysical phenomena. But even with the future E-ELT, single dish instruments are limited to a spatial resolution of about 4 mas in the visible. For the closest objects within our Galaxy most of the stellar photosphere remains smaller than 1 mas. With the success of long baseline interferometry these limitations were soom overcome. Today low and high resolution interferometric instruments on the VLTI and CHARA offer an immense range of astrophysical studies. Combining more telescopes and moving to visible wavelengths broadens the science cases even more. With the idea of developing strong science cases for a future visible interferometer, we organized a science group around the following topics: pre-main sequence and main sequence stars, fundamental parameters, asteroseismology and classical pulsating stars, evolved stars, massive stars, active galactic nuclei (AGNs) and imaging techniques. A meeting was organized on the 15th and 16th of January, 2015 in Nice with the support of the Action Specific in Haute Resolution Angulaire (ASHRA), the Programme National en Physique Stellaire (PNPS), the Lagrange Laboratory and the Observatoire de la Cote d'Azur, in order to present these cases and to discuss them further for future visible interferometers. This White Paper presents the outcome of the exchanges. This book is dedicated to the memory of our colleague Olivier Chesneau who passed away at the age of 41., Comment: White Paper prospective. This book is dedicated to the memory of our colleague Olivier Chesneau who passed away at the age of 41. v2 includes some corrections to text

Published

2017

28. Aperture synthesis imaging of the carbon AGB star R Sculptoris: Detection of a complex structure and a dominating spot on the stellar disk

Author

Wittkowski, Markus, De Gregorio-Monsalvo, Itziar, Eriksson, Kjell, Hron, Josef, Humphreys, Elizabeth M L, Lindqvist, Michael, Maercker, Matthias, Mohamed, Shazrene, Olofsson, Hans, Ramstedt, Sofia, Weigelt, Gerd, Hofmann, Karl Heinz, Höfner, Susanne, Le Bouquin, Jean Baptiste, Nowotny, Walter, Paladini, Claudia, Young, John, Berger, Jean-Philippe, Brunner, Matthias, Wittkowski, Markus, De Gregorio-Monsalvo, Itziar, Eriksson, Kjell, Hron, Josef, Humphreys, Elizabeth M L, Lindqvist, Michael, Maercker, Matthias, Mohamed, Shazrene, Olofsson, Hans, Ramstedt, Sofia, Weigelt, Gerd, Hofmann, Karl Heinz, Höfner, Susanne, Le Bouquin, Jean Baptiste, Nowotny, Walter, Paladini, Claudia, Young, John, Berger, Jean-Philippe, and Brunner, Matthias

Abstract

Aims. We present near-infrared interferometry of the carbon-rich asymptotic giant branch (AGB) star R Sculptoris (R Scl). Methods. We employ medium spectral resolution K-band interferometry obtained with the instrument AMBER at the Very Large Telescope Interferometer (VLTI) and H-band low spectral resolution interferometric imaging observations obtained with the VLTI instrument PIONIER. We compare our data to a recent grid of dynamic atmosphere and wind models. We compare derived fundamental parameters to stellar evolution models. Results. The visibility data indicate a broadly circular resolved stellar disk with a complex substructure. The observed AMBER squared visibility values show drops at the positions of CO and CN bands, indicating that these lines form in extended layers above the photosphere. The AMBER visibility values are best fit by a model without a wind. The PIONIER data are consistent with the same model. We obtain a Rosseland angular diameter of 8.9 ± 0.3 mas, corresponding to a Rosseland radius of 355 ± 55 R⊙, an effective temperature of 2640 ± 80 K, and a luminosity of log L/L⊙ = 3.74 ± 0.18. These parameters match evolutionary tracks of initial mass 1.5 ± 0.5 M⊙ and current mass 1.3 ± 0.7 M⊙. The reconstructed PIONIER images exhibit a complex structure within the stellar disk including a dominant bright spot located at the western part of the stellar disk. The spot has an H-band peak intensity of 40% to 60% above the average intensity of the limb-darkening-corrected stellar disk. The contrast between the minimum and maximum intensity on the stellar disk is about 1:2.5. Conclusions. Our observations are broadly consistent with predictions by dynamic atmosphere and wind models, although models with wind appear to have a circumstellar envelope that is too extended compared to our observations. The detected complex structure within the stellar disk is most likely caused by giant convection cells, resulting in large-scale shock fronts, and their effect, SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2017

29. Rings and filaments: The remarkable detached CO shell of U Antliae

Author

Kerschbaum, Franz, Maercker, Matthias, Brunner, Matthias, Lindqvist, Michael, Olofsson, Hans, Mecina, Marko, De Beck, E., Groenewegen, Martin A. T., Lagadec, Eric, Mohamed, S., Paladini, Claudia, Ramstedt, Sofia, Vlemmings, Wouter, Wittkowski, Markus, Kerschbaum, Franz, Maercker, Matthias, Brunner, Matthias, Lindqvist, Michael, Olofsson, Hans, Mecina, Marko, De Beck, E., Groenewegen, Martin A. T., Lagadec, Eric, Mohamed, S., Paladini, Claudia, Ramstedt, Sofia, Vlemmings, Wouter, and Wittkowski, Markus

Abstract

Aims. Our goal is to characterize the intermediate age, detached shell carbon star U Antliae morphologically and physically in order to study the mass-loss evolution after a possible thermal pulse. Methods. High spatial resolution ALMA observations of unprecedented quality in thermal CO lines allow us to derive first critical spatial and temporal scales and constrain modeling efforts to estimate mass-loss rates for both the present day as well as the ejection period of the detached shell. Results. The detached shell is remarkably thin, overall spherically symmetric, and shows a barely resolved filamentary substructure possibly caused by instabilities in the interaction zone of winds with different outflow velocities. The expansion age of the detached shell is of the order of 2700 years and its overall width indicates a high expansion-velocity and high mass-loss period of only a few hundred years at an average mass-loss rate of $\approx$ 10$^{-5}$ $M_\odot$ yr$^{-1}$. The post-high-mass-loss-rate-epoch evolution of U Ant shows a significant decline to a substantially lower gas expansion velocity and a mass-loss rate amounting to 4$\times$10$^{-8}$ $M_\odot$ yr$^{-1}$, at present being consistent with evolutionary changes as predicted for the period between thermal pulses. Rings and filaments: The remarkable detached CO shell of U Antliae. Available from: https://www.researchgate.net/publication/319035845_Rings_and_filaments_The_remarkable_detached_CO_shell_of_U_Antliae [accessed Sep 21, 2017]., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2017

30. To be or not to be Asymmetric? VLTI/MIDI and the Mass-loss Geometry of AGB Stars

Author

Paladini, Claudia, Klotz, Daniela, Sacuto, Stéphane, Lagadec, Eric, Wittkowski, Markus, Richichi, A., Hron, Josef, Jorissen, Alain, Groenewegen, Martin A. T., Kerschbaum, Franz, Verhoelst, Tijl, Rau, Gioia, Olofsson, Hans, Zhao-Geisler, Ronny, Matter, A., Paladini, Claudia, Klotz, Daniela, Sacuto, Stéphane, Lagadec, Eric, Wittkowski, Markus, Richichi, A., Hron, Josef, Jorissen, Alain, Groenewegen, Martin A. T., Kerschbaum, Franz, Verhoelst, Tijl, Rau, Gioia, Olofsson, Hans, Zhao-Geisler, Ronny, and Matter, A.

Abstract

info:eu-repo/semantics/published

Published

2017

31. Mass Losing Asymptotic Giant Branch Stars and Supergiants

Author

Whitelock, Patricia A., Boyer, Martha, Höfner, Susanne, Wittkowski, Markus, Zijlstra, Albert A., Whitelock, Patricia A., Boyer, Martha, Höfner, Susanne, Wittkowski, Markus, and Zijlstra, Albert A.

Abstract

This paper presents a summary of four invited and twelve contributed presentations on asymptotic giant branch stars and red supergiants, given over the course of two afternoon splinter sessions at the 19th Cool Stars Workshop. It highlights both recent observations and recent theory, with some emphasis on high spatial resolution, over a wide range of wavelengths. Topics covered include 3D models, convection, binary interactions, mass loss, dust formation and magnetic fields., Comment: To appear in the proceedings of the 19th Cambridge Workshop on Cool Stars, Stellar Systems and the Sun; 19 pages and 20 figures

Published

2016

32. A high-mass protobinary system with spatially resolved circumstellar accretion disks and circumbinary disk

Author

Kraus, Stefan, Kluska, Jacques, Kreplin, Alexander, Bate, Matthew, Harries, Tim J., Hofmann, Karl-Heinz, Hone, Edward, Monnier, John D., Weigelt, Gerd, Anugu, Narsireddy, de Wit, Willem-Jan, Wittkowski, Markus, Kraus, Stefan, Kluska, Jacques, Kreplin, Alexander, Bate, Matthew, Harries, Tim J., Hofmann, Karl-Heinz, Hone, Edward, Monnier, John D., Weigelt, Gerd, Anugu, Narsireddy, de Wit, Willem-Jan, and Wittkowski, Markus

Abstract

High-mass multiples might form via fragmentation of self-gravitational disks or alternative scenarios such as disk-assisted capture. However, only few observational constraints exist on the architecture and disk structure of high-mass protobinaries and their accretion properties. Here we report the discovery of a close ($57.9\pm0.2$mas=170au) high-mass protobinary, IRAS17216-3801, where our VLTI/GRAVITY+AMBER near-infrared interferometry allows us to image the circumstellar disks around the individual components with 3 milliarcsecond resolution. We estimate the component masses to $\sim20$ and $\sim18 M_{\odot}$ and find that the radial intensity profiles can be reproduced with an irradiated disk model, where the inner regions are excavated of dust, likely tracing the dust sublimation region in these disks. The circumstellar disks are strongly misaligned with respect to the binary separation vector, which indicates that the tidal forces did not have time to realign the disks, pointing towards a young dynamical age of the system. We constrain the distribution of the Br$\gamma$ and CO-emitting gas using VLTI/GRAVITY spectro-interferometry and VLT/CRIRES spectro-astrometry and find that the secondary is accreting at a higher rate than the primary. VLT/NACO imaging shows $L'$-band emission on 3-4 times larger scales than the binary separation, matching the expected dynamical truncation radius for the circumbinary disk. The IRAS17216-3801 system is $\sim3\times$ more massive and $\sim5\times$ more compact than other high-mass multiplies imaged at infrared wavelengths and the first high-mass protobinary system where circumstellar and circumbinary dust disks could be spatially resolved. This opens exciting new opportunities for studying star-disk interactions and the role of multiplicity in high-mass star formation., Comment: 9 pages, 4 figures, accepted for publication in The Astrophysical Journal Letters

Published

2016

33. Planet Formation Imager (PFI): science vision and key requirements

Author

Kraus, Stefan, Monnier, John D., Ireland, Michael J., Duchene, Gaspard, Espaillat, Catherine, Hoenig, Sebastian, Juhasz, Attila, Mordasini, Chris, Olofsson, Johan, Paladini, Claudia, Stassun, Keivan, Turner, Neal, Vasisht, Gautam, Harries, Tim J., Bate, Matthew R., Gonzalez, Jean-Francois, Matter, Alexis, Zhu, Zhaohuan, Panic, Olja, Regaly, Zsolt, Morbidelli, Alessandro, Meru, Farzana, Wolf, Sebastian, Ilee, John, Berger, Jean-Philippe, Zhao, Ming, Kral, Quentin, Morlok, Andreas, Bonsor, Amy, Ciardi, David, Kane, Stephen R., Kratter, Kaitlin, Laughlin, Greg, Pepper, Joshua, Raymond, Sean, Labadie, Lucas, Nelson, Richard P., Weigelt, Gerd, Brummelaar, Theo ten, Pierens, Arnaud, Oudmaijer, Rene, Kley, Wilhelm, Pope, Benjamin, Jensen, Eric L. N., Bayo, Amelia, Smith, Michael, Boyajian, Tabetha, Quiroga-Nunez, Luis Henry, Millan-Gabet, Rafael, Chiavassa, Andrea, Gallenne, Alexandre, Reynold, Mark, de Wit, Willem-Jan, Wittkowski, Markus, Millour, Florentin, Gandhi, Poshak, Almeida, Cristina Ramos, Herrero, Almudena Alonso, Packham, Chris, Kishimoto, Makoto, Tristram, Konrad R. W., Pott, Joerg-Uwe, Surdej, Jean, Buscher, David, Haniff, Chris, Lacour, Sylvestre, Petrov, Romain, Ridgway, Steve, Tuthill, Peter, van Belle, Gerard, Armitage, Phil, Baruteau, Clement, Benisty, Myriam, Bitsch, Bertram, Paardekooper, Sijme-Jan, Pinte, Christophe, Masset, Frederic, Rosotti, Giovanni P., Kraus, Stefan, Monnier, John D., Ireland, Michael J., Duchene, Gaspard, Espaillat, Catherine, Hoenig, Sebastian, Juhasz, Attila, Mordasini, Chris, Olofsson, Johan, Paladini, Claudia, Stassun, Keivan, Turner, Neal, Vasisht, Gautam, Harries, Tim J., Bate, Matthew R., Gonzalez, Jean-Francois, Matter, Alexis, Zhu, Zhaohuan, Panic, Olja, Regaly, Zsolt, Morbidelli, Alessandro, Meru, Farzana, Wolf, Sebastian, Ilee, John, Berger, Jean-Philippe, Zhao, Ming, Kral, Quentin, Morlok, Andreas, Bonsor, Amy, Ciardi, David, Kane, Stephen R., Kratter, Kaitlin, Laughlin, Greg, Pepper, Joshua, Raymond, Sean, Labadie, Lucas, Nelson, Richard P., Weigelt, Gerd, Brummelaar, Theo ten, Pierens, Arnaud, Oudmaijer, Rene, Kley, Wilhelm, Pope, Benjamin, Jensen, Eric L. N., Bayo, Amelia, Smith, Michael, Boyajian, Tabetha, Quiroga-Nunez, Luis Henry, Millan-Gabet, Rafael, Chiavassa, Andrea, Gallenne, Alexandre, Reynold, Mark, de Wit, Willem-Jan, Wittkowski, Markus, Millour, Florentin, Gandhi, Poshak, Almeida, Cristina Ramos, Herrero, Almudena Alonso, Packham, Chris, Kishimoto, Makoto, Tristram, Konrad R. W., Pott, Joerg-Uwe, Surdej, Jean, Buscher, David, Haniff, Chris, Lacour, Sylvestre, Petrov, Romain, Ridgway, Steve, Tuthill, Peter, van Belle, Gerard, Armitage, Phil, Baruteau, Clement, Benisty, Myriam, Bitsch, Bertram, Paardekooper, Sijme-Jan, Pinte, Christophe, Masset, Frederic, and Rosotti, Giovanni P.

Abstract

The Planet Formation Imager (PFI) project aims to provide a strong scientific vision for ground-based optical astronomy beyond the upcoming generation of Extremely Large Telescopes. We make the case that a breakthrough in angular resolution imaging capabilities is required in order to unravel the processes involved in planet formation. PFI will be optimised to provide a complete census of the protoplanet population at all stellocentric radii and over the age range from 0.1 to about 100 Myr. Within this age period, planetary systems undergo dramatic changes and the final architecture of planetary systems is determined. Our goal is to study the planetary birth on the natural spatial scale where the material is assembled, which is the "Hill Sphere" of the forming planet, and to characterise the protoplanetary cores by measuring their masses and physical properties. Our science working group has investigated the observational characteristics of these young protoplanets as well as the migration mechanisms that might alter the system architecture. We simulated the imprints that the planets leave in the disk and study how PFI could revolutionise areas ranging from exoplanet to extragalactic science. In this contribution we outline the key science drivers of PFI and discuss the requirements that will guide the technology choices, the site selection, and potential science/technology tradeoffs., Comment: 13 pages, 5 figures, Proceedings of SPIE 2016

Published

2016

34. A high-mass protobinary system with spatially resolved circumstellar accretion disks and circumbinary disk

Author

Kraus, Stefan, Kluska, Jacques, Kreplin, Alexander, Bate, Matthew, Harries, Tim J., Hofmann, Karl-Heinz, Hone, Edward, Monnier, John D., Weigelt, Gerd, Anugu, Narsireddy, de Wit, Willem-Jan, Wittkowski, Markus, Kraus, Stefan, Kluska, Jacques, Kreplin, Alexander, Bate, Matthew, Harries, Tim J., Hofmann, Karl-Heinz, Hone, Edward, Monnier, John D., Weigelt, Gerd, Anugu, Narsireddy, de Wit, Willem-Jan, and Wittkowski, Markus

Abstract

High-mass multiples might form via fragmentation of self-gravitational disks or alternative scenarios such as disk-assisted capture. However, only few observational constraints exist on the architecture and disk structure of high-mass protobinaries and their accretion properties. Here we report the discovery of a close ($57.9\pm0.2$mas=170au) high-mass protobinary, IRAS17216-3801, where our VLTI/GRAVITY+AMBER near-infrared interferometry allows us to image the circumstellar disks around the individual components with 3 milliarcsecond resolution. We estimate the component masses to $\sim20$ and $\sim18 M_{\odot}$ and find that the radial intensity profiles can be reproduced with an irradiated disk model, where the inner regions are excavated of dust, likely tracing the dust sublimation region in these disks. The circumstellar disks are strongly misaligned with respect to the binary separation vector, which indicates that the tidal forces did not have time to realign the disks, pointing towards a young dynamical age of the system. We constrain the distribution of the Br$\gamma$ and CO-emitting gas using VLTI/GRAVITY spectro-interferometry and VLT/CRIRES spectro-astrometry and find that the secondary is accreting at a higher rate than the primary. VLT/NACO imaging shows $L'$-band emission on 3-4 times larger scales than the binary separation, matching the expected dynamical truncation radius for the circumbinary disk. The IRAS17216-3801 system is $\sim3\times$ more massive and $\sim5\times$ more compact than other high-mass multiplies imaged at infrared wavelengths and the first high-mass protobinary system where circumstellar and circumbinary dust disks could be spatially resolved. This opens exciting new opportunities for studying star-disk interactions and the role of multiplicity in high-mass star formation., Comment: 9 pages, 4 figures, accepted for publication in The Astrophysical Journal Letters

Published

2016

35. Mass Losing Asymptotic Giant Branch Stars and Supergiants

Author

Whitelock, Patricia A., Boyer, Martha, Höfner, Susanne, Wittkowski, Markus, Zijlstra, Albert A., Whitelock, Patricia A., Boyer, Martha, Höfner, Susanne, Wittkowski, Markus, and Zijlstra, Albert A.

Abstract

This paper presents a summary of four invited and twelve contributed presentations on asymptotic giant branch stars and red supergiants, given over the course of two afternoon splinter sessions at the 19th Cool Stars Workshop. It highlights both recent observations and recent theory, with some emphasis on high spatial resolution, over a wide range of wavelengths. Topics covered include 3D models, convection, binary interactions, mass loss, dust formation and magnetic fields., Comment: To appear in the proceedings of the 19th Cambridge Workshop on Cool Stars, Stellar Systems and the Sun; 19 pages and 20 figures

Published

2016

36. Planet Formation Imager (PFI): science vision and key requirements

Author

Kraus, Stefan, Monnier, John D., Ireland, Michael J., Duchene, Gaspard, Espaillat, Catherine, Hoenig, Sebastian, Juhasz, Attila, Mordasini, Chris, Olofsson, Johan, Paladini, Claudia, Stassun, Keivan, Turner, Neal, Vasisht, Gautam, Harries, Tim J., Bate, Matthew R., Gonzalez, Jean-Francois, Matter, Alexis, Zhu, Zhaohuan, Panic, Olja, Regaly, Zsolt, Morbidelli, Alessandro, Meru, Farzana, Wolf, Sebastian, Ilee, John, Berger, Jean-Philippe, Zhao, Ming, Kral, Quentin, Morlok, Andreas, Bonsor, Amy, Ciardi, David, Kane, Stephen R., Kratter, Kaitlin, Laughlin, Greg, Pepper, Joshua, Raymond, Sean, Labadie, Lucas, Nelson, Richard P., Weigelt, Gerd, Brummelaar, Theo ten, Pierens, Arnaud, Oudmaijer, Rene, Kley, Wilhelm, Pope, Benjamin, Jensen, Eric L. N., Bayo, Amelia, Smith, Michael, Boyajian, Tabetha, Quiroga-Nunez, Luis Henry, Millan-Gabet, Rafael, Chiavassa, Andrea, Gallenne, Alexandre, Reynold, Mark, de Wit, Willem-Jan, Wittkowski, Markus, Millour, Florentin, Gandhi, Poshak, Almeida, Cristina Ramos, Herrero, Almudena Alonso, Packham, Chris, Kishimoto, Makoto, Tristram, Konrad R. W., Pott, Joerg-Uwe, Surdej, Jean, Buscher, David, Haniff, Chris, Lacour, Sylvestre, Petrov, Romain, Ridgway, Steve, Tuthill, Peter, van Belle, Gerard, Armitage, Phil, Baruteau, Clement, Benisty, Myriam, Bitsch, Bertram, Paardekooper, Sijme-Jan, Pinte, Christophe, Masset, Frederic, Rosotti, Giovanni P., Kraus, Stefan, Monnier, John D., Ireland, Michael J., Duchene, Gaspard, Espaillat, Catherine, Hoenig, Sebastian, Juhasz, Attila, Mordasini, Chris, Olofsson, Johan, Paladini, Claudia, Stassun, Keivan, Turner, Neal, Vasisht, Gautam, Harries, Tim J., Bate, Matthew R., Gonzalez, Jean-Francois, Matter, Alexis, Zhu, Zhaohuan, Panic, Olja, Regaly, Zsolt, Morbidelli, Alessandro, Meru, Farzana, Wolf, Sebastian, Ilee, John, Berger, Jean-Philippe, Zhao, Ming, Kral, Quentin, Morlok, Andreas, Bonsor, Amy, Ciardi, David, Kane, Stephen R., Kratter, Kaitlin, Laughlin, Greg, Pepper, Joshua, Raymond, Sean, Labadie, Lucas, Nelson, Richard P., Weigelt, Gerd, Brummelaar, Theo ten, Pierens, Arnaud, Oudmaijer, Rene, Kley, Wilhelm, Pope, Benjamin, Jensen, Eric L. N., Bayo, Amelia, Smith, Michael, Boyajian, Tabetha, Quiroga-Nunez, Luis Henry, Millan-Gabet, Rafael, Chiavassa, Andrea, Gallenne, Alexandre, Reynold, Mark, de Wit, Willem-Jan, Wittkowski, Markus, Millour, Florentin, Gandhi, Poshak, Almeida, Cristina Ramos, Herrero, Almudena Alonso, Packham, Chris, Kishimoto, Makoto, Tristram, Konrad R. W., Pott, Joerg-Uwe, Surdej, Jean, Buscher, David, Haniff, Chris, Lacour, Sylvestre, Petrov, Romain, Ridgway, Steve, Tuthill, Peter, van Belle, Gerard, Armitage, Phil, Baruteau, Clement, Benisty, Myriam, Bitsch, Bertram, Paardekooper, Sijme-Jan, Pinte, Christophe, Masset, Frederic, and Rosotti, Giovanni P.

Abstract

The Planet Formation Imager (PFI) project aims to provide a strong scientific vision for ground-based optical astronomy beyond the upcoming generation of Extremely Large Telescopes. We make the case that a breakthrough in angular resolution imaging capabilities is required in order to unravel the processes involved in planet formation. PFI will be optimised to provide a complete census of the protoplanet population at all stellocentric radii and over the age range from 0.1 to about 100 Myr. Within this age period, planetary systems undergo dramatic changes and the final architecture of planetary systems is determined. Our goal is to study the planetary birth on the natural spatial scale where the material is assembled, which is the "Hill Sphere" of the forming planet, and to characterise the protoplanetary cores by measuring their masses and physical properties. Our science working group has investigated the observational characteristics of these young protoplanets as well as the migration mechanisms that might alter the system architecture. We simulated the imprints that the planets leave in the disk and study how PFI could revolutionise areas ranging from exoplanet to extragalactic science. In this contribution we outline the key science drivers of PFI and discuss the requirements that will guide the technology choices, the site selection, and potential science/technology tradeoffs., Comment: 13 pages, 5 figures, Proceedings of SPIE 2016

Published

2016

37. Planet Formation Imager (PFI): science vision and key requirements

Author

Kraus, Stefan, Monnier, John J.D., Ireland, M.~J., Duchêne, Gaspard, Espaillat, C., Hönig, S., Juhasz, A., Mordasini, C., Olofsson, J., Paladini, Claudia, Stassun, K., Turner, Nils, Vasisht, G., Harries, T.~J., Bate, M.~R., Gonzalez, J.-F., Matter, A., Zhu, Z., Panic, O., Regaly, Z., Morbidelli, A., Meru, F., Wolf, S., Ilee, J., Berger, Jean-Philippe, Zhao, M., Kral, Q., Morlok, A., Bonsor, A., Ciardi, D., Kane, S.~R., Kratter, K., Laughlin, Greg, Pepper, J., Raymond, S., Labadie, L., Nelson, R.~P., Weigelt, G., Ten Brummelaar, Theo T.A., Pierens, A., Oudmaijer, R., Kley, W., Pope, B., Jensen, E.~L.~N., Bayo, A., Smith, M., Boyajian, Tabetha T.S., Quiroga-Nuñez, L.~H., Millan-Gabet, R., Chiavassa, Andréa, Gallenne, A., Reynolds, Mark, De Wit, Willem Jan, Wittkowski, Markus, Millour, F., Gandhi, Poshak R., Ramos Almeida, C., Alonso Herrero, A., Packham, C., Kishimoto, M., Tristram, K.~R.~W., Pott, J.-U., Surdej, J., Buscher, D., Haniff, C., Lacour, S., Petrov, R., Ridgway, S.~T., Tuthill, P., Van Belle, Gerard G.T., Armitage, P., Baruteau, C., Benisty, M., Bitsch, B., Paardekooper, S.-J., Pinte, C., Masset, F., Rosotti, G., Kraus, Stefan, Monnier, John J.D., Ireland, M.~J., Duchêne, Gaspard, Espaillat, C., Hönig, S., Juhasz, A., Mordasini, C., Olofsson, J., Paladini, Claudia, Stassun, K., Turner, Nils, Vasisht, G., Harries, T.~J., Bate, M.~R., Gonzalez, J.-F., Matter, A., Zhu, Z., Panic, O., Regaly, Z., Morbidelli, A., Meru, F., Wolf, S., Ilee, J., Berger, Jean-Philippe, Zhao, M., Kral, Q., Morlok, A., Bonsor, A., Ciardi, D., Kane, S.~R., Kratter, K., Laughlin, Greg, Pepper, J., Raymond, S., Labadie, L., Nelson, R.~P., Weigelt, G., Ten Brummelaar, Theo T.A., Pierens, A., Oudmaijer, R., Kley, W., Pope, B., Jensen, E.~L.~N., Bayo, A., Smith, M., Boyajian, Tabetha T.S., Quiroga-Nuñez, L.~H., Millan-Gabet, R., Chiavassa, Andréa, Gallenne, A., Reynolds, Mark, De Wit, Willem Jan, Wittkowski, Markus, Millour, F., Gandhi, Poshak R., Ramos Almeida, C., Alonso Herrero, A., Packham, C., Kishimoto, M., Tristram, K.~R.~W., Pott, J.-U., Surdej, J., Buscher, D., Haniff, C., Lacour, S., Petrov, R., Ridgway, S.~T., Tuthill, P., Van Belle, Gerard G.T., Armitage, P., Baruteau, C., Benisty, M., Bitsch, B., Paardekooper, S.-J., Pinte, C., Masset, F., and Rosotti, G.

Abstract

The Planet Formation Imager (PFI) project aims to provide a strong scientific vision for ground-based optical astronomy beyond the upcoming generation of Extremely Large Telescopes. We make the case that a breakthrough in angular resolution imaging capabilities is required in order to unravel the processes involved in planet formation. PFI will be optimised to provide a complete census of the protoplanet population at all stellocentric radii and over the age range from 0.1 to ∼100 Myr. Within this age period, planetary systems undergo dramatic changes and the final architecture of planetary systems is determined. Our goal is to study the planetary birth on the natural spatial scale where the material is assembled, which is the "Hill Sphere" of the forming planet, and to characterise the protoplanetary cores by measuring their masses and physical properties. Our science working group has investigated the observational characteristics of these young protoplanets as well as the migration mechanisms that might alter the system architecture. We simulated the imprints that the planets leave in the disk and study how PFI could revolutionise areas ranging from exoplanet to extragalactic science. In this contribution we outline the key science drivers of PFI and discuss the requirements that will guide the technology choices, the site selection, and potential science/technology tradeoffs., info:eu-repo/semantics/published

Published

2016

38. Dissecting the AGB star L2 Puppis: A torus in the making

Author

Lykou, Foteini, Lagadec, Eric, Wittkowski, Markus, Maercker, Matthias, Mayer, Andreas, Klotz, Daniela, Paladini, Claudia, Hron, Josef, Zijlstra, Albert A.A., Kluska, Jacques, Norris, Barnaby R M, Tuthill, Peter P.G., Ramstedt, Sofia, Lykou, Foteini, Lagadec, Eric, Wittkowski, Markus, Maercker, Matthias, Mayer, Andreas, Klotz, Daniela, Paladini, Claudia, Hron, Josef, Zijlstra, Albert A.A., Kluska, Jacques, Norris, Barnaby R M, Tuthill, Peter P.G., and Ramstedt, Sofia

Abstract

Aims. The circumstellar environment of L2 Pup, an oxygen-rich semiregular variable, was observed to understand the evolution of mass loss and the shaping of ejecta in the late stages of stellar evolution. Methods. High-angular resolution observations from a single 8 m telescope were obtained using aperture masking in the near-infrared (1.64, 2.30 and 3.74 μm) on the NACO/VLT, both in imaging and polarimetric modes. Results. The aperture-masking images of L2 Pup at 2.30 μm show a resolved structure that resembles a toroidal structure with a major axis of ∼140 milliarcseconds (mas) and an east-west orientation. Two clumps can be seen on either side of the star, ∼65 mas from the star, beyond the edge of the circumstellar envelope (estimated diameter is ∼27 mas), while a faint, hook-like structure appear toward the northeast. The patterns are visible both in the imaging and polarimetric mode, although the latter was only used to measure the total intensity (Stokes I). The overall shape of the structure is similar at the 3.74 μm pseudo-continuum (dust emission), where the clumps appear to be embedded within a dark, dusty lane. The faint, hook-like patterns are also seen at this wavelength, extending northeast and southwest with the central, dark lane being an apparent axis of symmetry. We interpret the structure as a circumstellar torus with inner radius of 4.2au. With a rotation velocity of 10 kms-1 as suggested by the SiO maser profile, we estimate a stellar mass of 0.7M⊙., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2015

39. From the atmosphere to the circumstellar environment in cool evolved stars

Author

Wittkowski, Markus, Paladini, Claudia, Wittkowski, Markus, and Paladini, Claudia

Abstract

We discuss and illustrate contributions that optical interferometry has made on our current understanding of cool evolved stars. We include red giant branch (RGB) stars, asymptotic giant branch (AGB) stars, and red supergiants (RSGs). Studies using optical interferometry from visual to mid-infrared wavelengths have greatly increased our knowledge of their atmospheres, extended molecular shells, dust formation, and winds. These processes and the morphology of the circumstellar environment are important for the further evolution of these stars toward planetary nebulae (PNe) and core-collapse supernovae (SNe), and for the return of material to the interstellar medium., Comment: To appear in the Book of the VLTI School 2013, held 9-21 Sep 2013 Barcelonnette (France), "What the highest angular resolution can bring to stellar astrophysics?", Ed. Millour, Chiavassa, Bigot, Chesneau, Meilland, Stee, EAS Publications Series (2015)

Published

2015

40. From the atmosphere to the circumstellar environment in cool evolved stars

Author

Wittkowski, Markus, Paladini, Claudia, Wittkowski, Markus, and Paladini, Claudia

Abstract

We discuss and illustrate contributions that optical interferometry has made on our current understanding of cool evolved stars. We include red giant branch (RGB) stars, asymptotic giant branch (AGB) stars, and red supergiants (RSGs). Studies using optical interferometry from visual to mid-infrared wavelengths have greatly increased our knowledge of their atmospheres, extended molecular shells, dust formation, and winds. These processes and the morphology of the circumstellar environment are important for the further evolution of these stars toward planetary nebulae (PNe) and core-collapse supernovae (SNe), and for the return of material to the interstellar medium., Comment: To appear in the Book of the VLTI School 2013, held 9-21 Sep 2013 Barcelonnette (France), "What the highest angular resolution can bring to stellar astrophysics?", Ed. Millour, Chiavassa, Bigot, Chesneau, Meilland, Stee, EAS Publications Series (2015)

Published

2015

41. PIONIERing Diameter Measurements of Globular Cluster Giants

Author

Hron, Josef, Bouquin, J.~L., Lebzelter, Thomas, Paladini, Claudia, Soszynski, I., Berger, Jean-Philippe, Boffin, Henri, Wittkowski, Markus, Hron, Josef, Bouquin, J.~L., Lebzelter, Thomas, Paladini, Claudia, Soszynski, I., Berger, Jean-Philippe, Boffin, Henri, and Wittkowski, Markus

Abstract

info:eu-repo/semantics/published

Published

2015

42. VLTI/MIDI Large Program: AGB Stars at Different Spatial Scales

Author

Paladini, Claudia, Klotz, Daniela, Wittkowski, Markus, Hron, Josef, Richichi, A., Lagadec, Eric, Verhoelst, T., Rau, Gioia, Sacuto, Stéphane, Jorissen, Alain, Groenewegen, Martin, Olofsson, Hans, Kerschbaum, Franz, Paladini, Claudia, Klotz, Daniela, Wittkowski, Markus, Hron, Josef, Richichi, A., Lagadec, Eric, Verhoelst, T., Rau, Gioia, Sacuto, Stéphane, Jorissen, Alain, Groenewegen, Martin, Olofsson, Hans, and Kerschbaum, Franz

Abstract

info:eu-repo/semantics/published

Published

2015

43. Unraveling Disks in AGB Stars

Author

Lykou, Foteini, Ramstedt, Sofia, Maercker, Matthias, Hron, Josef, Zijlstra, Albert A.A., Tuthill, Peter P.G., Norris, Barnaby R M, Kluska, Jacques, Paladini, Claudia, Lagadec, Eric, Wittkowski, Markus, Lykou, Foteini, Ramstedt, Sofia, Maercker, Matthias, Hron, Josef, Zijlstra, Albert A.A., Tuthill, Peter P.G., Norris, Barnaby R M, Kluska, Jacques, Paladini, Claudia, Lagadec, Eric, and Wittkowski, Markus

Abstract

It is commonly accepted that asymmetries found in the post-AGB stars and planetary nebulae should originate as early as during the AGB phase. We present results from our high-angular resolution observing programs, with an aperture masking technique on the VLT, of a sample of evolved stars that were known to present asymmetries at larger spatial scales (e.g. jets, torii and/or bipolar nebulae). Disk-like structures have been found in the vicinity of at least two of these stars., SCOPUS: cp.k, info:eu-repo/semantics/published

Published

2015

44. From the atmosphere to the circumstellar environment in cool evolved stars

Author

Wittkowski, Markus, Paladini, Claudia, Wittkowski, Markus, and Paladini, Claudia

Abstract

We discuss and illustrate contributions that optical interferometry has made on our current understanding of cool evolved stars. We include red giant branch (RGB) stars, asymptotic giant branch (AGB) stars, and red supergiants (RSGs). Studies using optical interferometry from visual to mid-infrared wavelengths have greatly increased our knowledge of their atmospheres, extended molecular shells, dust formation, and winds. These processes and the morphology of the circumstellar environment are important for the further evolution of these stars toward planetary nebulae (PNe) and core-collapse supernovae (SNe), and for the return of material to the interstellar medium., SCOPUS: cp.k, info:eu-repo/semantics/published

Published

2015

45. Erratum: Dissecting the AGB star L 2 Puppis: A torus in the making (Astronomy and Astrophysics (2015) 576 (A46) DOI: 10.1051/0004-6361/201322828)

Author

Lykou, Foteini, Lagadec, Eric, Wittkowski, Markus, Maercker, Matthias, Mayer, Andreas, Klotz, Daniela, Paladini, Claudia, Hron, Josef, Zijlstra, Albert A.A., Kluska, Jacques, Norris, Barnaby R M, Tuthill, Peter P.G., Ramstedt, Sofia, Lykou, Foteini, Lagadec, Eric, Wittkowski, Markus, Maercker, Matthias, Mayer, Andreas, Klotz, Daniela, Paladini, Claudia, Hron, Josef, Zijlstra, Albert A.A., Kluska, Jacques, Norris, Barnaby R M, Tuthill, Peter P.G., and Ramstedt, Sofia

Abstract

SCOPUS: er.j, info:eu-repo/semantics/published

Published

2015

46. VLTI status update: a decade of operations and beyond

Author

Merand, Antoine, Abuter, Roberto, Aller-Carpentier, Emmanuel, Andolfato, Luigi, Alonso, Jaime, Berger, Jean-Philippe, Blanchard, Guillaume, Boffin, Henri, Bourget, Pierre, Bristow, Paul, Cid, Claudia, de Wit, Willem-Jan, del Valle, Diego, Delplancke-Stroebele, Franccoise, Derie, Frederic, Faundez, Lorena, Ertel, Steve, Grellmann, Rebekka, Gitton, Philippe, Glindemann, Andreas, Guajardo, Patricia, Guieu, Sylvain, Guisard, Stephane, Guniat, Serge, Haguenauer, Pierre, Herrera, Christian, Hummel, Christian, La Fuente, Carlos, Lopez, Marcelo, Mardones, Pedro, Morel, Sebastien, Mueller, Andre, Percheron, Isabelle, Duc, Than Phan, Pino, Andres, Poupar, Sebastien, Pozna, Eszter, Ramirez, Andres, Rengaswamy, Sridharan, Rivas, Lionel, Rivinius, Thomas, Segovia, Alex, Schmid, Christian, Schoeller, Markus, Schuhler, Nicolas, Woillez, Julien, Wittkowski, Markus, Merand, Antoine, Abuter, Roberto, Aller-Carpentier, Emmanuel, Andolfato, Luigi, Alonso, Jaime, Berger, Jean-Philippe, Blanchard, Guillaume, Boffin, Henri, Bourget, Pierre, Bristow, Paul, Cid, Claudia, de Wit, Willem-Jan, del Valle, Diego, Delplancke-Stroebele, Franccoise, Derie, Frederic, Faundez, Lorena, Ertel, Steve, Grellmann, Rebekka, Gitton, Philippe, Glindemann, Andreas, Guajardo, Patricia, Guieu, Sylvain, Guisard, Stephane, Guniat, Serge, Haguenauer, Pierre, Herrera, Christian, Hummel, Christian, La Fuente, Carlos, Lopez, Marcelo, Mardones, Pedro, Morel, Sebastien, Mueller, Andre, Percheron, Isabelle, Duc, Than Phan, Pino, Andres, Poupar, Sebastien, Pozna, Eszter, Ramirez, Andres, Rengaswamy, Sridharan, Rivas, Lionel, Rivinius, Thomas, Segovia, Alex, Schmid, Christian, Schoeller, Markus, Schuhler, Nicolas, Woillez, Julien, and Wittkowski, Markus

Abstract

We present the latest update of the European Southern Observatory's Very Large Telescope interferometer (VLTI). The operations of VLTI have greatly improved in the past years: reduction of the execution time; better offering of telescopes configurations; improvements on AMBER limiting magnitudes; study of polarization effects and control for single mode fibres; fringe tracking real time data, etc. We present some of these improvements and also quantify the operational improvements using a performance metric. We take the opportunity of the first decade of operations to reflect on the VLTI community which is analyzed quantitatively and qualitatively. Finally, we present briefly the preparatory work for the arrival of the second generation instruments GRAVITY and MATISSE., Comment: 10 pages, 7 figures, Proceedings of the SPIE, 9146-19

Published

2014

47. The wonderful complexity of the Mira AB system

Author

Ramstedt, Sofia, Sacuto, Stéphane, Mohamed, Shazrene, Vlemmings, Wouter, Maercker, Matthias, De Beck, E., Lindqvist, Michael, Olofsson, Hans, Montez, Rodolfo, Baudry, Alain, Humphreys, Elizabeth M L, Wittkowski, Markus, Jorissen, Alain, Paladini, Claudia, Kerschbaum, Franz, Mayer, Andreas, Cox, Nick L J, Lagadec, Eric, Leal-Ferreira, Marcelo M.L., Pérez-Sánchez, Andrés, Ramstedt, Sofia, Sacuto, Stéphane, Mohamed, Shazrene, Vlemmings, Wouter, Maercker, Matthias, De Beck, E., Lindqvist, Michael, Olofsson, Hans, Montez, Rodolfo, Baudry, Alain, Humphreys, Elizabeth M L, Wittkowski, Markus, Jorissen, Alain, Paladini, Claudia, Kerschbaum, Franz, Mayer, Andreas, Cox, Nick L J, Lagadec, Eric, Leal-Ferreira, Marcelo M.L., and Pérez-Sánchez, Andrés

Abstract

We have mapped the 12CO(3-2) line emission around the Mira AB system at 0.5 resolution using the Atacama Large Millimeter/submillimeter Array (ALMA). The CO map shows amazing complexity. The circumstellar gas has been shaped by different dynamical actors during the evolution of the system, and several morphological components can be identified. The companion is marginally resolved in continuum emission and is currently at 0. 487 ± 0. 006 separation. In the main line component, centered on the stellar velocity, spiral arcs around Mira A are found. The spiral appears to be relatively flat and oriented in the orbital plane. An accretion wake behind the companion is clearly visible, and the projected arc separation is about 5′′. In the blue wing of the line emission, offset from the main line, several large (~5-10′′) opposing arcs are found. We tentatively suggest that this structure is created by the wind of Mira B blowing a bubble in the expanding envelope of Mira A., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2014

48. A VLTI survey of dusty envelopes of AGB stars

Author

Paladini, Claudia, Klotz, Daniela, Sacuto, Stéphane, Lagadec, Eric, Wittkowski, Markus, Hron, Josef, Jorissen, Alain, Groenewegen, Martin A. T., Kerschbaum, Franz, Verhoelst, T., Richichi, A., Olofsson, Hans, Paladini, Claudia, Klotz, Daniela, Sacuto, Stéphane, Lagadec, Eric, Wittkowski, Markus, Hron, Josef, Jorissen, Alain, Groenewegen, Martin A. T., Kerschbaum, Franz, Verhoelst, T., Richichi, A., and Olofsson, Hans

Abstract

info:eu-repo/semantics/published

Published

2014

49. Asymmetries start in the AGB phase

Author

Lykou, F., Klotz, Daniela, Hron, Josef, Paladini, Claudia, Jorissen, Alain, Chesneau, Olivier, Lagadec, Eric, Zijlstra, A.A., Tuthill, P., Norris, B., Monnier, J., Kluska, J., Ramstedt, Sofia, Wittkowski, Markus, Maercker, Matthias, Lykou, F., Klotz, Daniela, Hron, Josef, Paladini, Claudia, Jorissen, Alain, Chesneau, Olivier, Lagadec, Eric, Zijlstra, A.A., Tuthill, P., Norris, B., Monnier, J., Kluska, J., Ramstedt, Sofia, Wittkowski, Markus, and Maercker, Matthias

Abstract

info:eu-repo/semantics/published

Published

2014

50. The wonderful complexity of the Mira AB system

Author

Ramstedt, Sofia, Sacuto, Stéphane, Mohamed, Shazrene, Vlemmings, Wouter, Maercker, Matthias, De Beck, E., Lindqvist, Michael, Olofsson, Hans, Montez, Rodolfo, Baudry, Alain, Humphreys, Elizabeth M L, Wittkowski, Markus, Jorissen, Alain, Paladini, Claudia, Kerschbaum, Franz, Mayer, Andreas, Cox, Nick L J, Lagadec, Eric, Leal-Ferreira, Marcelo M.L., Pérez-Sánchez, Andrés, Ramstedt, Sofia, Sacuto, Stéphane, Mohamed, Shazrene, Vlemmings, Wouter, Maercker, Matthias, De Beck, E., Lindqvist, Michael, Olofsson, Hans, Montez, Rodolfo, Baudry, Alain, Humphreys, Elizabeth M L, Wittkowski, Markus, Jorissen, Alain, Paladini, Claudia, Kerschbaum, Franz, Mayer, Andreas, Cox, Nick L J, Lagadec, Eric, Leal-Ferreira, Marcelo M.L., and Pérez-Sánchez, Andrés

Abstract

We have mapped the 12CO(3-2) line emission around the Mira AB system at 0.5 resolution using the Atacama Large Millimeter/submillimeter Array (ALMA). The CO map shows amazing complexity. The circumstellar gas has been shaped by different dynamical actors during the evolution of the system, and several morphological components can be identified. The companion is marginally resolved in continuum emission and is currently at 0. 487 ± 0. 006 separation. In the main line component, centered on the stellar velocity, spiral arcs around Mira A are found. The spiral appears to be relatively flat and oriented in the orbital plane. An accretion wake behind the companion is clearly visible, and the projected arc separation is about 5′′. In the blue wing of the line emission, offset from the main line, several large (~5-10′′) opposing arcs are found. We tentatively suggest that this structure is created by the wind of Mira B blowing a bubble in the expanding envelope of Mira A., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2014