Chemoarchaeological downsizing in a hierarchical universe: impact of a top-heavy IGIMF

Gargiulo, Ignacio D.; Cora, S. A.; Padilla, Nelson; Muñoz-Arancibia, A.; Ruiz, Andrés N.; Orsi, Álvaro; Tecce, T. E.; Weidner, C.; Bruzual, G.

doi:10.1093/mnras/stu2272

Cited by 79 publications

(101 citation statements)

References 133 publications

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“…This feature remains a shared standard for semi-analytic models in general (see the latest versions of other models, e.g. Gargiulo et al 2015;Henriques et al 2015;Lacey et al 2016). If subhaloes were able to accrete hot gas from the ICM within a semi-analytic framework, this should systematically raise H i fractions and lower quiescent fractions.…”

Section: Caveats Discussion and Conclusionmentioning

confidence: 96%

Physical drivers of galaxies’ cold-gas content: exploring environmental and evolutionary effects with Dark Sage

Stevens

Brown

2017

Monthly Notices of the Royal Astronomical Society

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We combine the latest spectrally stacked data of 21-cm emission from the ALFALFA survey with an updated version of the Dark Sage semi-analytic model to investigate the relative contributions of secular and environmental astrophysical processes on shaping the H i fractions and quiescence of galaxies in the local Universe. We calibrate the model to match the observed mean H i fraction of all galaxies as a function of stellar mass. Without consideration of stellar feedback, disc instabilities, and active galactic nuclei, we show how the slope and normalisation of this relation would change significantly. We find Dark Sage can reproduce the relative impact that halo mass is observed to have on satellites' H i fractions and quiescent fraction. However, the model satellites are systematically gas-poor. We discuss how this could be affected by satellite-central cross-contamination from the group-finding algorithm applied to the observed galaxies, but that it is not the full story. From our results, we suggest the anti-correlation between satellites' H i fractions and host halo mass, seen at fixed stellar mass and fixed specific star formation rate, can be attributed almost entirely to ram-pressure stripping of cold gas. Meanwhile, stripping of hot gas from around the satellites drives the correlation of quiescent fraction with halo mass at fixed stellar mass. Further detail in the modelling of galaxy discs' centres is required to solidify this result, however. We contextualise our results with those from other semi-analytic models and hydrodynamic simulations.

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Section: Caveats Discussion and Conclusionmentioning

confidence: 96%

Physical drivers of galaxies’ cold-gas content: exploring environmental and evolutionary effects with Dark Sage

Stevens

Brown

2017

Monthly Notices of the Royal Astronomical Society

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“…Simultaneously explaining the increasing α-to-Fe ratio with velocity dispersion (or stellar mass) and increasing stellar metallicity with stellar mass is therefore fundamentally difficult within the current framework of galaxy formation. One possible solution would be the introduction of a variable IMF which becomes more top-heavy for a higher SFR as suggested by Calura & Menci (2009) and Gargiulo et al (2015) and previously suggested on independent grounds by Baugh et al (2005) and Lacey et al (2016).…”

Section: S U M M a Ry A N D Discussionmentioning

confidence: 99%

“…They found that a combination of a power-law DTD and metal-rich winds, which drive light α elements directly out of galaxies, gives the best agreement with a wide range of observational data including the [α/Fe]-mass and mass-metallicity relations. On the other hand, Gargiulo et al (2015) employed a variable IMF whose slope becomes shallower (more top-heavy) for a higher SFR of a galaxy. They tuned their model to reproduce the observed [α/Fe]-galaxy mass relation, and they claimed that the SFR-dependent IMF is key to reproducing the [α/Fe]-galaxy mass relation and that a short star formation time-scale due to radio-mode AGN feedback alone cannot explain the slope of the relation.…”

Section: Introductionmentioning

confidence: 99%

The metal enrichment of passive galaxies in cosmological simulations of galaxy formation

Okamoto

Nagashima

Lacey

et al. 2016

Mon. Not. R. Astron. Soc.

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“…While the treatment of mergers is the same as the one implemented in previous versions of SAG, many aspects of DI have been modified for the purposes of the present study. Both mechanisms trigger starbursts that involve a timescale that regulates the consumption of the cold gas involved in the process as implemented by Gargiulo et al (2015), instead of being instantaneous as in former versions of SAG. We refer the reader to their work for more details about the treatment of extended bursts.…”

Section: Bulge Formation Mechanismsmentioning

confidence: 99%

“…It follows the production of eleven chemical elements (H, 4 He, 12 C, 14 N, 16 O, 20 Ne, 24 Mg, 28 Si, 32 S, 40 Ca, 56 Fe) generated by stars in different mass ranges. As described in Gargiulo et al (2015), we adopt a new set of stellar yields given by Karakas (2010), (Hirschi et al 2005) and Kobayashi et al (2006) for low and intermediate-mass stars (mass interval 1 − 8M ⊙ ), for the mass loss of pre-supernova stars (He and CNO elements), and for the explosive nucleosynthesis (SNe CC), respectively, all of them corresponding to solar metallicities. These yields are selected to be in accordance with the large number of constraints for the Milky Way (Romano et al 2010).…”

Section: Chemical Enrichment Modelmentioning

confidence: 99%

Stellar Populations in a semi-analytic model I: Bulges of Milky Way-like galaxies

Gargiulo¹,

Cora

Vega-Martínez³

et al. 2017

Monthly Notices of the Royal Astronomical Society

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We study the stellar populations of bulges of Milky Way-like (MW-like) galaxies with the aim of identifying the physical processes involved in the formation of the bulge of our Galaxy. We use the semi-analytic model of galaxy formation and evolution SAG adapted to this aim; this kind of models can trace the properties of galaxies and their components like stellar discs, bulges and halos, but resolution limits prevent them from reaching the scale of stellar populations (SPs). Properties of groups of stars formed during single star formation events are stored and tracked in the model and results are compared with observations of stars in the galactic bulge. MW-like galaxies are selected using two different criteria. One of them considers intrinsic photo-metric properties and the second is focused on the cosmological context of the local group of galaxies (LG). We compare our model results with spectroscopic and photometric stellar metallicity distributions. We find that 87% of stars in bulges of MWtype galaxies in our model are accreted and formed in starbursts during disc instability events. Mergers contribute to 13% of the mass budget of the bulge and are responsible for the low metallicity tail of the distribution. Abundance ratios of α elements with respect to iron, [α/Fe], are measured in SPs of model galaxies. The patterns found in the model for SPs with different origins help to explain the lack of a gradient of [α/Fe] ratios in observed stars along the minor axis of the bulge.

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Chemoarchaeological downsizing in a hierarchical universe: impact of a top-heavy IGIMF

Cited by 79 publications

References 133 publications

Physical drivers of galaxies’ cold-gas content: exploring environmental and evolutionary effects with Dark Sage

Physical drivers of galaxies’ cold-gas content: exploring environmental and evolutionary effects with Dark Sage

The metal enrichment of passive galaxies in cosmological simulations of galaxy formation

Stellar Populations in a semi-analytic model I: Bulges of Milky Way-like galaxies

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