Using population synthesis of massive stars to study the interstellar medium near OB associations

Voss, R.; Diehl, R.; Hartmann, D. H.; Cerviño, M.; Vink, J. S.; Meynet, Georges; Limongi, Marco; Chieffi, A.

doi:10.1051/0004-6361/200912260

Cited by 84 publications

(134 citation statements)

References 58 publications

(106 reference statements)

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“…For these groups of massive stars, we used the population synthesis results from Voss et al (2009; Al is largely completed after about 48 Myr, the lifetime of stars of about 8 M , also broadly consistent with the age estimates for HI supershells given by Bagetakos et al (2011). Not all the stars in a cluster might form at the same time.…”

Section: Which Star Clusters Produce How Much 26 Al?mentioning

confidence: 83%

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²⁶Al kinematics: superbubbles following the spiral arms?

Krause

Diehl

Bagetakos

et al. 2015

A&A

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Context. High-energy resolution spectroscopy of the 1.8 MeV radioactive decay line of 26 Al with the SPI instrument onboard the INTEGRAL satellite has recently revealed that diffuse 26 Al has higher velocities than other components of the interstellar medium in the Milky Way. 26 Al shows Galactic rotation in the same sense as the stars and other gas tracers, but reaches excess velocities of up to 300 km s −1 . Aims. We investigate whether this result can be understood in the context of superbubbles, taking into account the statistics of young star clusters and H I supershells as well as the association of young star clusters with spiral arms. Methods. We derived energy output and 26 Al mass of star clusters as a function of the cluster mass by population synthesis from stellar evolutionary tracks of massive stars. Using the limiting cases of weakly and strongly dissipative superbubble expansion, we linked this to the size distribution of H I supershells and assessed the properties of possible 26 Al-carrying superbubbles. Results. 26 Al is produced by star clusters of all masses above ≈200 M , is roughly equally contributed over a logarithmic star cluster mass scale and strongly linked to the injection of feedback energy. The observed superbubble size distribution cannot be related to the star cluster mass function in a straightforward manner. To avoid the added volume of all superbubbles exceeding the volume of the Milky Way, individual superbubbles have to merge frequently. If any two superbubbles merge, or if 26 Al is injected off-centre into a larger HI supershell, we expect the hot 26 Al-carrying gas to obtain velocities of the order of the typical sound speed in superbubbles, ≈300 km s −1 before decay. For star formation coordinated by the spiral arm pattern which, inside co-rotation, is overtaken by the faster moving stars and gas, outflows from spiral arm star clusters would preferentially flow into the cavities that are inflated by previous star formation associated with this arm. These cavities would preferentially be located towards the leading edge of a given arm. Conclusions. This scenario might explain the 26 Al kinematics. The massive-star ejecta are expected to survive ≥10 6 yr before being recycled into next-generation stars.

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Section: Which Star Clusters Produce How Much 26 Al?mentioning

confidence: 83%

“…For each star cluster, we first determined the masses of its stars above 8 M by the optimal sampling method, the amount of released 26 Al from Voss et al (2009), taking into account radioactive decay, and finally averaged over time (48 Myr). The result is shown in Fig.…”

Section: Which Star Clusters Produce How Much 26 Al?mentioning

confidence: 99%

²⁶Al kinematics: superbubbles following the spiral arms?

Krause

Diehl

Bagetakos

et al. 2015

A&A

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“…Particularly interesting would be the 60 Fe/ 26 Al ratio for source populations of specific ages, as the ratio varies significantly due to wind-released 26 Al before any core-collapse supernova would eject 60 Fe and more 26 Al [139]. 60 Fe is exclusively released in supernovae, although predominantly produced in the late shell-burning phase before the collapse of the core.…”

Section: Al and 60 Fe From Massive Starsmentioning

confidence: 99%

Cosmic Gamma-Ray Spectroscopy

Diehl

2013

Astronomical Review

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Penetrating gamma-rays require complex instrumentation for astronomical spectroscopy measurements of gamma-rays from cosmic sources. Multiple-interaction detectors in space combined with sophisticated postprocessing of detector events on ground have lead to a spectroscopy performance which is now capable to provide new astrophysical insights. Spectral signatures in the MeV regime originate from transitions in the nuclei of atoms (rather than in their electron shell). Nuclear transitions are stimulated by either radioactive decays or high-energy nuclear collisions such as with cosmic rays. Gamma-ray lines have been detected from radioactive isotopes produced in nuclear burning inside stars and supernovae, and from energetic-particle interactions in solar flares. Radioactive-decay gamma-rays from 56 Ni directly reflect the source of supernova light. 44 Ti is produced in core-collapse supernova interiors, and the paucity of corresponding 44 Ti gamma-ray line sources reflects the variety of dynamical conditions herein. 26 Al and 60 Fe are dispersed in interstellar space from massive-star nucleosynthesis over millions of years. Gamma-rays from their decay are measured in detail by gamma-ray telescopes, astrophysical interpretations reach from massive-star interiors to dynamical processes in the interstellar medium. Nuclear de-excitation gamma-ray lines have been found in solar-flare events, and convey information about energetic-particle production in these events, and their interaction in the solar atmosphere. The annihilation of positrons leads to another type of cosmic gamma-ray source. The characteristic annihilation gamma-rays at 511 keV have been measured long ago in solar flares, and now throughout the interstellar medium of our Milky Way galaxy. But now a puzzle has appeared, as a surprising predominance of the central bulge region was determined. This requires either new positron sources or transport processes not yet known to us. In this paper we discuss instrumentation and data processing for cosmic gamma-ray spectroscopy, and the astrophysical issues and insights from these measurements.

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“…The time-dependent energy and mass input from OB associations, as calculated by Voss et al (2009) is implemented in the code as a source term in the energy and in the mass equations following a reference table. In the same way, the heating and cooling rates typical of a solar metallicity gas are tabulated for various densities and temperatures and added or subtracted accordingly from the energy budget of each cell at every time step.…”

Section: Numerical Simulationsmentioning

confidence: 99%

Formation of cold filaments from colliding superbubbles

et al. 2013

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Abstract. We present results from numerical simulations of expanding and colliding supershells. These large-scale spherical shocks, created by the combined feedback from several OB stars, are unstable to a number of hydrodynamical instabilities, so they quickly fragment into cold and highly structured clumps. A collision between two large shells can organize these small clumps into very filamentary structures, of tens of parsecs length and less than a parsec thick. In simulations where the flow of stellar material is followed with a tracer quantity, cold structures practically do not contain any enriched material from the OB associations at the time of their creation. In this context then, the clumps are created almost exclusively out of diffuse ISM material, containing almost no wind or supernova matter. Although the mechanism presented here is possibly not the only route for filament creation, this predicted property may help identify regions of sequential star formation.

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Using population synthesis of massive stars to study the interstellar medium near OB associations

Cited by 84 publications

References 58 publications

²⁶Al kinematics: superbubbles following the spiral arms?

²⁶Al kinematics: superbubbles following the spiral arms?

Cosmic Gamma-Ray Spectroscopy

Formation of cold filaments from colliding superbubbles

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Using population synthesis of massive stars to study the interstellar medium near OB associations

Cited by 84 publications

References 58 publications

26Al kinematics: superbubbles following the spiral arms?

26Al kinematics: superbubbles following the spiral arms?

Cosmic Gamma-Ray Spectroscopy

Formation of cold filaments from colliding superbubbles

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²⁶Al kinematics: superbubbles following the spiral arms?

²⁶Al kinematics: superbubbles following the spiral arms?