Impact of AGN feedback on galaxies and their multiphase ISM across cosmic time

Valentini, Milena; Murante, Giuseppe; Borgani, S.; Granato, G. L.; Monaco, Pierluigi; Brighenti, Fabrizio; Tornatore, L.; Bressan, A.; Lapi, A.

doi:10.1093/mnras/stz3131

Cited by 25 publications

(43 citation statements)

References 150 publications

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“…in runs that varied the coupling between angular momentum and the suppression factor (their fig. 11;Valentini et al 2020 report similar results for their independent implementation). Suitable changes to other subgrid parameters can compensate for this difference and lead to realistic star formation histories with a standard Bondi-Hoyle-Lyttleton accretion formula.…”

Section: Discussionsupporting

confidence: 56%

The importance of black hole repositioning for galaxy formation simulations

Bahé,

Schaye,

Schaller

et al. 2021

Preprint

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Active galactic nucleus (AGN) feedback from accreting supermassive black holes (SMBHs) is an essential ingredient of galaxy formation simulations. The orbital evolution of SMBHs is affected by dynamical friction that cannot be predicted self-consistently by contemporary simulations of galaxy formation in representative volumes. Instead, such simulations typically use a simple "repositioning" of SMBHs, but the effects of this approach on SMBH and galaxy properties have not yet been investigated systematically. Based on a suite of smoothed particle hydrodynamics simulations with the code and a Bondi-Hoyle-Lyttleton subgrid gas accretion model, we investigate the impact of repositioning on SMBH growth and on other baryonic components through AGN feedback. Across at least a factor ∼1000 in mass resolution, SMBH repositioning (or an equivalent approach) is a necessary prerequisite for AGN feedback; without it, black hole growth is negligible. Limiting the effective repositioning speed to 10 km s −1 delays the onset of AGN feedback and severely limits its impact on stellar mass growth in the centre of massive galaxies. Repositioning has three direct physical consequences. It promotes SMBH mergers and thus accelerates their initial growth. In addition, it raises the peak density of the ambient gas and reduces the SMBH velocity relative to it, giving a combined boost to the accretion rate that can reach many orders of magnitude. Our results suggest that a more sophisticated and/or better calibrated treatment of SMBH repositioning is a critical step towards more predictive galaxy formation simulations.

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Section: Discussionsupporting

confidence: 56%

The importance of black hole repositioning for galaxy formation simulations

Bahé,

Schaye,

Schaller

et al. 2021

Preprint

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“…'quasar'-mode and 'radio'-mode) depending on the BH accretion rate. Also, 𝜖 f varies significantly from one model to another: for instance, in their hydrodynamical simulations, Valentini et al (2020) implemented the coupling between the AGN energy and a realistic multi-phase ISM, finding that 𝜖 f ∼ 10 −2 adequately regulates the BH growth in Milky Way-like galaxies. A simplification that we adopted here is the absence of an AGN duty cycle: our model assumes a continuous feeding for the BH, corresponding to a continuous energy output distributed over the entire galaxy lifespan, whereas the observed AGN activity is intermittent.…”

Section: Limitations Of Our Modelmentioning

confidence: 99%

A universal relation between the properties of supermassive black holes, galaxies, and dark matter halos

Marasco,

Cresci,

Posti

et al. 2021

Preprint

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We study the relations between the mass of the central black hole (BH) 𝑀 BH , the dark matter halo mass 𝑀 h , and the stellar-to-halo mass fraction 𝑓 ★ ∝ 𝑀 ★ /𝑀 h in a sample of 55 nearby galaxies with dynamically measured 𝑀 BH > 10 6 M and 𝑀 h > 5×10 11 M . The main improvement with respect to previous studies is that we consider both early-and late-type systems for which 𝑀 h is determined either from globular cluster dynamics or from spatially resolved rotation curves. Independently of their structural properties, galaxies in our sample build a well defined sequence in the 𝑀 BH -𝑀 h -𝑓 ★ space. We find that: (i) 𝑀 h and 𝑀 BH strongly correlate with each other and anti-correlate with 𝑓 ★ ; (ii) there is a break in the slope of the 𝑀 BH -𝑀 h relation at 𝑀 h of 10 12 M , and in the 𝑓 ★ -𝑀 BH relation at 𝑀 BH of ∼ 10 7 −10 8 M ; (iii) at a fixed 𝑀 BH , galaxies with a larger 𝑓 ★ tend to occupy lighter halos and to have later morphological types.We show that the observed trends can be reproduced by a simple equilibrium model in the ΛCDM framework where galaxies smoothly accrete dark and baryonic matter at a cosmological rate, having their stellar and black hole build-up regulated both by the cooling of the available gas reservoir and by the negative feedback from star formation and active galactic nuclei (AGN). Feature (ii) arises as the BH population transits from a rapidly accreting phase to a more gentle and self-regulated growth, while scatter in the AGN feedback efficiency can account for feature (iii).

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“…The sub-resolution model that we adopt for our cosmological simulations is MUPPI (MUlti Phase Particle Integrator): it represents a multiphase ISM and accounts for a variety of physical processes which occur on scales not explicitly resolved. The model has been introduced and thoroughly described in Murante et al (2010Murante et al ( , 2015 and Valentini et al (2017Valentini et al ( , 2019Valentini et al ( , 2020: in this Section, we outline its main features, while we refer the reader to the aformentioned papers for a more comprehensive discussion and any further details.…”

Section: The Sub-resolution Modelmentioning

confidence: 99%

“…Wind particles receiving energy use it to increase their velocity along their least resistance path, since they are kicked against their own density gradient. We refer the interested reader to the aforementioned papers (Murante et al 2010(Murante et al , 2015Valentini et al 2017Valentini et al , 2019 for a thorough description of all the processes included in our sub-resolution model; in particular, Section 2 of Valentini et al (2020) provides a comprehensive summary and can be taken as a reference for the values of all the parameters not explicitly mentioned here. A gas particle exits the multiphase stage when its density drops below a density threshold (0.2𝜌 thresh ) or once a maximum time (set by the dynamical time of the cold gas) elapses.…”

Section: Star Formation and Stellar Feedbackmentioning

confidence: 99%

Host galaxies of high-redshift quasars: supermassive black hole growth and feedback

Valentini,

Gallerani,

Ferrara

2021

Preprint

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The properties of quasar-host galaxies might be determined by the growth and feedback of their supermassive (SMBH, 10 8−10 M ) black holes. We investigate such connection with a suite of cosmological simulations of massive (halo mass ≈ 10 12 M ) galaxies at 𝑧 6 which include a detailed sub-grid multiphase gas and accretion model. BH seeds of initial mass 10 5 M grow mostly by gas accretion, and become SMBH by 𝑧 = 6 setting on the observed 𝑀 BH − 𝑀 ★ relation without the need for a boost factor. Although quasar feedback crucially controls the SMBH growth, its impact on the properties of the host galaxy at 𝑧 = 6 is negligible. In our model, quasar activity can both quench (via gas heating) or enhance (by ISM over-pressurization) star formation. However, we find that the star formation history is insensitive to such modulation as it is largely dominated, at least at 𝑧 > 6, by cold gas accretion from the environment that cannot be hindered by the quasar energy deposition. Although quasar-driven outflows can achieve velocities > 1000 km s −1 , only ≈ 4% of the outflowing gas mass can actually escape from the host galaxy. These findings are only loosely constrained by available data, but can guide observational campaigns searching for signatures of quasar feedback in early galaxies.

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Impact of AGN feedback on galaxies and their multiphase ISM across cosmic time

Cited by 25 publications

References 150 publications

The importance of black hole repositioning for galaxy formation simulations

The importance of black hole repositioning for galaxy formation simulations

A universal relation between the properties of supermassive black holes, galaxies, and dark matter halos

Host galaxies of high-redshift quasars: supermassive black hole growth and feedback

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