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From starburst to quenching : merger-driven evolution of the star formation regimes in a shell galaxy

Petersson, Jonathan ; Renaud, Florent LU ; Agertz, Oscar LU ; Dekel, Avishai and Duc, Pierre Alain (2023) In Monthly Notices of the Royal Astronomical Society 518(3). p.3261-3273
Abstract

Shell galaxies make a class of tidally distorted galaxies, characterized by wide concentric arc(s), extending out to large galactocentric distances with sharp outer edges. Recent observations of young massive star clusters in the prominent outer shell of NGC 474 suggest that such systems host extreme conditions of star formation. In this paper, we present a hydrodynamic simulation of a galaxy merger and its transformation into a shell galaxy. We analyse how the star formation activity evolves with time, location-wise within the system, and what are the physical conditions for star formation. During the interaction, an excess of dense gas appears, triggering a starburst, i.e. an enhanced star formation rate and a reduced depletion time.... (More)

Shell galaxies make a class of tidally distorted galaxies, characterized by wide concentric arc(s), extending out to large galactocentric distances with sharp outer edges. Recent observations of young massive star clusters in the prominent outer shell of NGC 474 suggest that such systems host extreme conditions of star formation. In this paper, we present a hydrodynamic simulation of a galaxy merger and its transformation into a shell galaxy. We analyse how the star formation activity evolves with time, location-wise within the system, and what are the physical conditions for star formation. During the interaction, an excess of dense gas appears, triggering a starburst, i.e. an enhanced star formation rate and a reduced depletion time. Star formation coincides with regions of high-molecular gas fraction, such as the galactic nucleus, spiral arms, and occasionally the tidal debris during the early stages of the merger. Tidal interactions scatter stars into a stellar spheroid, while the gas cools down and reforms a disc. The morphological transformation after coalescence stabilizes the gas and thus quenches star formation, without the need for feedback from an active galactic nucleus. This evolution shows similarities with a compaction scenario for compact quenched spheroids at high-redshift, yet without a long red nugget phase. Shells appear after coalescence, during the quenched phase, implying that they do not host the conditions necessary for in situ star formation. The results suggest that shell-forming mergers might be part of the process of turning blue late-type galaxies into red and dead early-types.

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author
; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
galaxies: interactions, galaxies: star formation, galaxies: starburst, methods: numerical
in
Monthly Notices of the Royal Astronomical Society
volume
518
issue
3
pages
13 pages
publisher
Oxford University Press
external identifiers
  • scopus:85149247665
ISSN
0035-8711
DOI
10.1093/mnras/stac3136
language
English
LU publication?
yes
id
933bcc31-4bc8-497f-a0b6-013b6b40b3dc
date added to LUP
2024-01-12 13:37:14
date last changed
2024-01-12 13:39:35
@article{933bcc31-4bc8-497f-a0b6-013b6b40b3dc,
  abstract     = {{<p>Shell galaxies make a class of tidally distorted galaxies, characterized by wide concentric arc(s), extending out to large galactocentric distances with sharp outer edges. Recent observations of young massive star clusters in the prominent outer shell of NGC 474 suggest that such systems host extreme conditions of star formation. In this paper, we present a hydrodynamic simulation of a galaxy merger and its transformation into a shell galaxy. We analyse how the star formation activity evolves with time, location-wise within the system, and what are the physical conditions for star formation. During the interaction, an excess of dense gas appears, triggering a starburst, i.e. an enhanced star formation rate and a reduced depletion time. Star formation coincides with regions of high-molecular gas fraction, such as the galactic nucleus, spiral arms, and occasionally the tidal debris during the early stages of the merger. Tidal interactions scatter stars into a stellar spheroid, while the gas cools down and reforms a disc. The morphological transformation after coalescence stabilizes the gas and thus quenches star formation, without the need for feedback from an active galactic nucleus. This evolution shows similarities with a compaction scenario for compact quenched spheroids at high-redshift, yet without a long red nugget phase. Shells appear after coalescence, during the quenched phase, implying that they do not host the conditions necessary for in situ star formation. The results suggest that shell-forming mergers might be part of the process of turning blue late-type galaxies into red and dead early-types.</p>}},
  author       = {{Petersson, Jonathan and Renaud, Florent and Agertz, Oscar and Dekel, Avishai and Duc, Pierre Alain}},
  issn         = {{0035-8711}},
  keywords     = {{galaxies: interactions; galaxies: star formation; galaxies: starburst; methods: numerical}},
  language     = {{eng}},
  month        = {{01}},
  number       = {{3}},
  pages        = {{3261--3273}},
  publisher    = {{Oxford University Press}},
  series       = {{Monthly Notices of the Royal Astronomical Society}},
  title        = {{From starburst to quenching : merger-driven evolution of the star formation regimes in a shell galaxy}},
  url          = {{http://dx.doi.org/10.1093/mnras/stac3136}},
  doi          = {{10.1093/mnras/stac3136}},
  volume       = {{518}},
  year         = {{2023}},
}