Search for Galactic runaway stars using <i>Gaia</i> Data Release 1 and HIPPARCOS proper motions

Apellániz, J. Maíz; González, M. Pantaleoni; Barbá, R. H.; Diaz, Sébastien; Negueruela, I.; Lennon, D. J.; Sota, A.; Paez, E.

doi:10.1051/0004-6361/201832787

Cited by 52 publications

(55 citation statements)

References 87 publications

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“…Although this agrees with runaway fraction for O stars in a 10 3.5 M cluster (Oh & Kroupa 2016), it is not universal and observational data indicates that this fraction can be significantly lower with variations with stellar type. Maíz Apellániz et al (2018) estimated the fraction at 10 − 12% for the O stars and ∼ 6% for B stars, which is also in agreement with those from Eldridge et al (2011) when correcting for completeness. The results shown here could therefore overestimate the impact of runaway stars.…”

Section: Limitations Of the Modelsupporting

confidence: 77%

“…While a collisionless approximation is valid on galactic scales, star-star interactions drive the internal dynamics of dense star clusters. As a result, some fraction of OB stars are kicked out of their natal star clusters with velocities large enough to move them out of the dense star forming gas before exploding as SNe (e.g., Gies & Bolton 1986;Gies 1987;Stone 1991;Hoogerwerf et al 2000;Schilbach & Röser 2008;Jilinski et al 2010;Silva & Napiwotzki 2011;Maíz Apellániz et al 2018). Simulation of clusters (e.g., Oh & Kroupa 2016) reveal that such velocity kicks originates from gravitational interactions (Poveda et al 1967), including the disruption of binaries through SNe (Blaauw 1961).…”

Section: Introductionmentioning

confidence: 99%

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How runaway stars boost galactic outflows

Andersson

Agertz

2020

Monthly Notices of the Royal Astronomical Society

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Roughly ten per cent of OB stars are kicked out of their natal clusters before ending their life as supernovae. These so called runaway stars can travel hundreds of parsecs into the low-density interstellar medium, where momentum and energy from stellar feedback is efficiently deposited. In this work we explore how this mechanism affects large scale properties of the galaxy, such as outflows. To do so we use a new model which treats OB stars and their associated feedback processes on a star-by-star basis. With this model we compare two hydrodynamical simulations of Milky Way-like galaxies, one where we include runaways, and one where we ignore them. Including runaway stars leads to twice as many supernovae explosions in regions with gas densities ranging from 10 −5 cm −3 to 10 −3 cm −3 . This results in more efficient heating of the inter-arm regions, and drives strong galactic winds with mass loading factors boosted by up to one order of magnitude. These outflows produce a more massive and extended multi-phase circumgalactic medium, as well as a population of dense clouds in the halo. Conversely, since less energy and momentum is released in the dense star forming regions, the cold phase of the interstellar medium is less disturbed by feedback effects.

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Section: Limitations Of the Modelsupporting

confidence: 77%

Section: Introductionmentioning

confidence: 99%

How runaway stars boost galactic outflows

Andersson

Agertz

2020

Monthly Notices of the Royal Astronomical Society

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“…Testori et al (2006) mention that Hoogerwerf et al (2001) identified a B-type runaway star (HD 64760, HIP 38518), and suggested it was ejected in a binary-supernova scenario that took place in the Vela OB2 region. The identification of hypervelocity stars from Gaia data (Renzo et al 2018;Marchetti et al 2018;Maíz Apellániz et al 2018;Irrgang et al 2018) might tell us whether other such objects are compatible with an origin inside the IVS. A full dynamical modelling of the orbits of hypervelocity stars and nearby open clusters is beyond of the scope of this study, but should be possible based on the 3D velocities of these objects (Soubiran et al 2018).…”

Section: Discussionmentioning

confidence: 99%

A ring in a shell: the large-scale 6D structure of the Vela OB2 complex

Cantat-Gaudin

Mapelli

Balaguer-Núñez

et al. 2019

A&A

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Context. The Vela OB2 association is a group of ∼10 Myr stars exhibiting a complex spatial and kinematic substructure. The all-sky Gaia DR2 catalogue contains proper motions, parallaxes (a proxy for distance), and photometry that allow us to separate the various components of Vela OB2. Aims. We characterise the distribution of the Vela OB2 stars on a large spatial scale, and study its internal kinematics and dynamic history. Methods. We make use of Gaia DR2 astrometry and published Gaia-ESO Survey data. We apply an unsupervised classification algorithm to determine groups of stars with common proper motions and parallaxes. Results. We find that the association is made up of a number of small groups, with a total current mass over 2330 M . The threedimensional distribution of these young stars trace the edge of the gas and dust structure known as the IRAS Vela Shell across ∼180 pc and shows clear signs of expansion. Conclusions. We propose a common history for Vela OB2 and the IRAS Vela Shell. The event that caused the expansion of the shell happened before the Vela OB2 stars formed, imprinted the expansion in the gas the stars formed from, and most likely triggered star formation.

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“…SB1. McSwain et al (2004) determined the SB1 orbit of this γ-ray binary, which is also a runaway star (Maíz Apellániz et al 2018b). We classified it as ON6 V((f))z in GOSSS III.…”

Section: Sagittarius-sagittamentioning

confidence: 99%

“…SB1?. Underhill & Matthews (1995) calculated a SB1 orbit for this runaway star (Maíz Apellániz et al 2018b). The orbit has not been confirmed and it is possible that the radial velocity variations are caused by pulsations.…”

Section: Sagittarius-sagittamentioning

confidence: 99%

MONOS: Multiplicity Of Northern O-type Spectroscopic systems

Apellániz

Paez

Negueruela

et al. 2019

A&A

Self Cite

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Context. Multiplicity in massive stars is key to understanding the chemical and dynamical evolution of galaxies. Among massive stars, those of O type play a crucial role due to their high masses and short lifetimes. Aims. MONOS (Multiplicity Of Northern O-type Spectroscopic systems) is a project designed to collect information and study O-type spectroscopic binaries with δ > −20 • . In this first paper we describe the sample and provide spectral classifications and additional information for objects with previous spectroscopic and/or eclipsing binary orbits. In future papers we will test the validity of previous solutions and calculate new spectroscopic orbits. Methods. The spectra in this paper have two sources: the Galactic O-Star Spectroscopic Survey (GOSSS), a project that obtains blueviolet R ∼ 2500 spectroscopy of thousands of massive stars, and LiLiMaRlin, a library of libraries of high-resolution spectroscopy of massive stars obtained from four different surveys (CAFÉ-BEANS, OWN, IACOB, and NoMaDS) and additional data from our own observing programs and public archives. We have also used lucky images obtained with AstraLux. Results. We present homogeneous spectral classifications for 92 O-type spectroscopic multiple systems and ten optical companions, many of them original. We discuss the visual multiplicity of each system with the support of AstraLux images and additional sources. For eleven O-type objects and for six B-type objects we present their first GOSSS spectral classifications. For two known eclipsing binaries we detect double absorption lines (SB2) or a single moving line (SB1) for the first time, to which we add a third system reported by us recently. For two previous SB1 systems we detect their SB2 nature for the first time and give their first separate spectral classifications, something we have also done for a third object just recently identified as a SB2. We also detect nine new astrometric companions and provide updated information on several others. We emphasize the results for two stars: for σ Ori AaAbB we provide spectral classifications for the three components with a single observation for the first time thanks to a lucky spectroscopy observation obtained close to the Aa,Ab periastron and for θ 1 Ori CaCb we add it to the class of Galactic Of?p stars, raising the number of its members to six. Our sample of O-type spectroscopic binaries contains more triple-or higher-order systems than double systems.

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Search for Galactic runaway stars using Gaia Data Release 1 and HIPPARCOS proper motions

Cited by 52 publications

References 87 publications

How runaway stars boost galactic outflows

How runaway stars boost galactic outflows

A ring in a shell: the large-scale 6D structure of the Vela OB2 complex

MONOS: Multiplicity Of Northern O-type Spectroscopic systems

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