First results from the IllustrisTNG simulations: the stellar mass content of groups and clusters of galaxies

Pillepich, Annalisa; Nelson, Dylan; Hernquist, Lars; Springel, Volker; Pakmor, Rüdiger; Torrey, Paul; Weinberger, Rainer; Genel, Shy; Naiman, Jill; Marinacci, Federico; Vogelsberger, Mark

doi:10.1093/mnras/stx3112

Cited by 1,414 publications

(1,453 citation statements)

References 118 publications

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“…Illus-trisTNG is the successor to the Illustris simulations (see below), with numerous updates that are described in the public data release (Nelson et al 2019). Weinberger et al (2018) and Pillepich et al (2018a) provide a complete description of the physical models. Additional details about these simulations are given by Pillepich et al (2018b), Springel et al (2018), Nelson et al (2018), Naiman et al (2018), and Marinacci et al (2018).…”

Section: The Illustristng Simulationsmentioning

confidence: 99%

“…The baryonic simulations follow the evolution of dark matter, stars, gas and supermassive black holes from a redshift of 127 to the present epoch using the AREPO moving-mesh code (Springel 2010). Star formation occurs above a threshold density criterion, and is regulated by a subgrid model for the interstellar medium (Springel & Hernquist 2003;Nelson et al 2015;Pillepich et al 2018a). Where needed for stellar evolution and mass return calculations, a Chabrier (2003) initial mass function is used.…”

Section: The Illustristng Simulationsmentioning

confidence: 99%

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Interacting galaxies in the IllustrisTNG simulations - I: Triggered star formation in a cosmological context

Patton

Wilson

Metrow

et al. 2020

Monthly Notices of the Royal Astronomical Society

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We use the IllustrisTNG cosmological hydrodynamical simulations to investigate how the specific star formation rates (sSFRs) of massive galaxies (M * > 10 10 M ) depend on the distance to their closest companions. We estimate sSFR enhancements by comparing with control samples that are matched in redshift, stellar mass, local density and isolation, and we restrict our analysis to pairs with stellar mass ratios of 0.1 to 10. At small separations (∼ 15 kpc), the mean sSFR is enhanced by a factor of 2.0 ± 0.1 in the flagship (110.7 Mpc) 3 simulation (TNG100-1). Statistically significant enhancements extend out to 3D separations of 280 kpc in the (302.6 Mpc) 3 simulation (TNG300-1). We find similar trends in the EAGLE and Illustris simulations, although their sSFR enhancements are lower than those in TNG100-1 by about a factor of two. Enhancements in IllustrisTNG galaxies are seen throughout the redshift range explored (0 z < 1), with the strength of the enhancements decreasing with increasing redshift for galaxies with close companions. In order to more closely compare with observational results, we separately consider 2D projected distances between galaxies in IllustrisTNG. We detect significant sSFR enhancements out to projected separations of 260 kpc in TNG300-1, with projection effects diluting the size of the enhancements by about 20 per cent below 50 kpc. We find similar sSFR enhancements in TNG100-1 and Sloan Digital Sky Survey galaxies, with enhancements extending out to projected separations of about 150 kpc for star-forming galaxies at z < 0.2. Finally, by summing over all separations, we estimate that the presence of closest companions boosts the average sSFR of massive galaxies in TNG100-1 by 14.5 per cent.

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Section: The Illustristng Simulationsmentioning

confidence: 99%

Section: The Illustristng Simulationsmentioning

confidence: 99%

Interacting galaxies in the IllustrisTNG simulations - I: Triggered star formation in a cosmological context

Patton

Wilson

Metrow

et al. 2020

Monthly Notices of the Royal Astronomical Society

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“…But this simple model ignores non-spherical and non-gravitational effects such as hierarchical mergers driven by large-scale filaments and feedback by star formation, supernovae, and active galactic nuclei (AGN). A central focus of recent observations and modern simulations has been on understanding these non-gravitational effects and feedback processes, which leads to a comprehensive understanding of the ways in which the galaxies are forming and evolving as a function of their host halo mass and redshift (McCarthy et al 2017;Pillepich et al 2018b;Mulroy et al 2019). While the first principle approaches have been made progress in making more realistic galaxy population, empirical approaches are complementary in gaining insight into the physics of these systems.…”

Section: Introductionmentioning

confidence: 99%

Aging haloes: implications of the magnitude gap on conditional statistics of stellar and gas properties of massive haloes

Farahi

Trac

2020

Monthly Notices of the Royal Astronomical Society

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Cold dark matter model predicts that the large-scale structure grows hierarchically. Small dark matter halos form first. Then, they grow gradually via continuous merger and accretion. These halos host the majority of baryonic matter in the Universe in the form of hot gas and cold stellar phase. Determining how baryons are partitioned into these phases requires detailed modeling of galaxy formation and their assembly history. It is speculated that formation time of the same mass halos might be correlated with their baryonic content. To evaluate this hypothesis, we employ halos of mass above 10 14 M realized by TNG300 solution of the IllustrisTNG project. Formation time is not directly observable. Hence, we rely on the magnitude gap between the brightest and the fourth brightest halo galaxy member, which is shown that traces formation time of the host halo. We compute the conditional statistics of the stellar and gas content of halos conditioned on their total mass and magnitude gap. We find a strong correlation between magnitude gap and gas mass, BCG stellar mass, and satellite galaxies stellar mass, but not the total stellar mass of halo. Conditioning on the magnitude gap can reduce the scatter about halo property-halo mass relation and has a significant impact on the conditional covariance. Reduction in the scatter can be as significant as 30%, which implies more accurate halo mass prediction. Incorporating the magnitude gap has a potential to improve cosmological constraints using halo abundance and allows us to gain insight into the baryon evolution within these systems.

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“…Numerical simulations (e.g., Oser et al 2010;Wellons et al 2015), semi-analytic models (SAM; e.g., Lee & Yi 2013, 2017, and stellar-mass-halo-mass (SHAM) analyses (e.g., Moster et al 2013Moster et al , 2018Behroozi et al 2013b;Rodríguez-Puebla et al 2017) generally show that the fraction of accreted stars through mergers increase with total galaxy stellar mass or halo mass (e.g., Lackner et al 2012;Cooper et al 2013;Rodriguez-Gomez et al 2016;Qu et al 2017;Pillepich et al 2018). For example, Qu et al (2017) analyzed the mass assembly of central galaxies in the EA-GLE cosmological simulation and found that ∼ 20% of the stellar mass of present day massive galaxies (> 10 11 M ) is built up through mergers, and more massive galaxies have experienced more stellar-mass growth by mergers.…”

Section: Introductionmentioning

confidence: 99%

On the (Lack of) Evolution of the Stellar Mass Function of Massive Galaxies from z = 1.5 to 0.4

Kawinwanichakij

Papovich

Ciardullo

et al. 2020

ApJ

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We study the evolution in the number density of the highest mass galaxies over 0.4 < z < 1.5 (covering 9 Gyr). We use the Spitzer/HETDEX Exploratory Large-Area (SHELA) Survey, which covers 17.5 deg 2 with eight photometric bands spanning 0.3-4.5 µm within the SDSS Stripe 82 field. This size produces the lowest counting uncertainties and cosmic variance yet for massive galaxies at z ∼ 1.0. We study the stellar mass function (SMF) for galaxies with log(M * /M ) > 10.3 using a forward-modeling method that fully accounts for statistical and systematic uncertainties on stellar mass. From z=0.4 to 1.5 the massive end of the SMF shows minimal evolution in its shape: the characteristic mass (M * ) evolves by less than 0.1 dex (±0.05 dex); the number density of galaxies with log M * /M > 11 stays roughly constant at log(n/Mpc −3 ) −3.4 (±0.05), then declines to log n/Mpc −3 =−3.7 (±0.05) at z=1.5. We discuss the uncertainties in the SMF, which are dominated by assumptions in the star formation history and details of stellar population synthesis models for stellar mass estimations. For quiescent galaxies, the data are consistent with no (or slight) evolution ( 0.1 dex) in the characteristic mass nor number density from z ∼ 1.5 to the present. This implies that any mass growth (presumably through "dry' mergers) of the quiescent massive galaxy population must balance the rate of mass losses from late-stage stellar evolution and the formation of quenching galaxies from the star-forming population. We provide a limit on this mass growth from z = 1.0 to 0.4 of ∆M * /M * ≤ 45% (i.e., 0.16 dex) for quiescent galaxies more massive than 10 11 M .

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First results from the IllustrisTNG simulations: the stellar mass content of groups and clusters of galaxies

Cited by 1,414 publications

References 118 publications

Interacting galaxies in the IllustrisTNG simulations - I: Triggered star formation in a cosmological context

Interacting galaxies in the IllustrisTNG simulations - I: Triggered star formation in a cosmological context

Aging haloes: implications of the magnitude gap on conditional statistics of stellar and gas properties of massive haloes

On the (Lack of) Evolution of the Stellar Mass Function of Massive Galaxies from z = 1.5 to 0.4

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