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Gas in globular clusters - I. Gas retention and its possible consequences

Bobrick, Alexey LU orcid ; Davies, Melvyn B. LU and Perets, Hagai B. (2025) In Monthly Notices of the Royal Astronomical Society 544(4). p.3601-3616
Abstract

Globular clusters host complex stellar populations whose chemical signatures suggest early (-) retention and reprocessing of stellar ejecta, yet direct evidence for intracluster gas is lacking. Here we present a unified theoretical framework for the evolution of gas in young globular clusters, and its implications for the production of multiple stellar populations. We show that low-velocity AGB winds are gravitationally retained in clusters more massive than a few. In addition, AGB winds in such clusters collide with each other and the previously retained winds, triggering a rapid 'switch' to efficient gas retention. Expected gas retention fractions agree well with the observed second population fractions in Galactic globular clusters.... (More)

Globular clusters host complex stellar populations whose chemical signatures suggest early (-) retention and reprocessing of stellar ejecta, yet direct evidence for intracluster gas is lacking. Here we present a unified theoretical framework for the evolution of gas in young globular clusters, and its implications for the production of multiple stellar populations. We show that low-velocity AGB winds are gravitationally retained in clusters more massive than a few. In addition, AGB winds in such clusters collide with each other and the previously retained winds, triggering a rapid 'switch' to efficient gas retention. Expected gas retention fractions agree well with the observed second population fractions in Galactic globular clusters. Furthermore, the accumulated gas cannot form new stars because protostellar cores are disrupted by encounters with pre-existing stars. Instead, the gas is accreted onto pre-existing main-sequence stars and compact objects. Time-dependent core-halo models indicate that compact objects can grow and collapse within -, while lower-mass main-sequence stars can be 'rejuvenated' into the 4- range required to reproduce key abundance patterns. Therefore, in our model, the multiple populations will be found in sufficiently massive clusters, with the second-population stars being formed from the inner subset of first-population stars that accreted large fractions of their mass from the AGB-processed retained gas. Finally, we argue that a combination of feedback processes, including accretion luminosity onto compact objects, novae, pulsar winds, and binary supernovae, will clear the gas by, thus reproducing the gas-poor conditions observed for present-day clusters.

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author
; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
astrochemistry, circumstellar matter, globular clusters: general, stars: chemically peculiar, stars: formation, stars: mass-loss
in
Monthly Notices of the Royal Astronomical Society
volume
544
issue
4
pages
16 pages
publisher
Oxford University Press
external identifiers
  • scopus:105024065953
ISSN
0035-8711
DOI
10.1093/mnras/staf1925
language
English
LU publication?
yes
additional info
Publisher Copyright: © 2025 The Author(s). Published by Oxford University Press on behalf of Royal Astronomical Society.
id
02c059c0-a0b2-42c3-bde7-f2b0729645ad
date added to LUP
2026-02-16 13:18:21
date last changed
2026-02-17 02:23:18
@article{02c059c0-a0b2-42c3-bde7-f2b0729645ad,
  abstract     = {{<p>Globular clusters host complex stellar populations whose chemical signatures suggest early (-) retention and reprocessing of stellar ejecta, yet direct evidence for intracluster gas is lacking. Here we present a unified theoretical framework for the evolution of gas in young globular clusters, and its implications for the production of multiple stellar populations. We show that low-velocity AGB winds are gravitationally retained in clusters more massive than a few. In addition, AGB winds in such clusters collide with each other and the previously retained winds, triggering a rapid 'switch' to efficient gas retention. Expected gas retention fractions agree well with the observed second population fractions in Galactic globular clusters. Furthermore, the accumulated gas cannot form new stars because protostellar cores are disrupted by encounters with pre-existing stars. Instead, the gas is accreted onto pre-existing main-sequence stars and compact objects. Time-dependent core-halo models indicate that compact objects can grow and collapse within -, while lower-mass main-sequence stars can be 'rejuvenated' into the 4- range required to reproduce key abundance patterns. Therefore, in our model, the multiple populations will be found in sufficiently massive clusters, with the second-population stars being formed from the inner subset of first-population stars that accreted large fractions of their mass from the AGB-processed retained gas. Finally, we argue that a combination of feedback processes, including accretion luminosity onto compact objects, novae, pulsar winds, and binary supernovae, will clear the gas by, thus reproducing the gas-poor conditions observed for present-day clusters.</p>}},
  author       = {{Bobrick, Alexey and Davies, Melvyn B. and Perets, Hagai B.}},
  issn         = {{0035-8711}},
  keywords     = {{astrochemistry; circumstellar matter; globular clusters: general; stars: chemically peculiar; stars: formation; stars: mass-loss}},
  language     = {{eng}},
  month        = {{11}},
  number       = {{4}},
  pages        = {{3601--3616}},
  publisher    = {{Oxford University Press}},
  series       = {{Monthly Notices of the Royal Astronomical Society}},
  title        = {{Gas in globular clusters - I. Gas retention and its possible consequences}},
  url          = {{http://dx.doi.org/10.1093/mnras/staf1925}},
  doi          = {{10.1093/mnras/staf1925}},
  volume       = {{544}},
  year         = {{2025}},
}