Your search keyword '"Davies, Jonathan J."' showing total 7 results

1. Are the fates of supermassive black holes and galaxies determined by individual mergers, or by the properties of their host haloes?

Author

Davies, Jonathan J, Pontzen, Andrew, and Crain, Robert A

Subjects

*SUPERMASSIVE black holes, *MERGERS & acquisitions, *PROPERTIES of matter, *GALAXY mergers, *GALAXIES, *BINDING energy

Abstract

The fates of massive galaxies are tied to the evolution of their central supermassive black holes (BHs), due to the influence of AGN feedback. Correlations within simulated galaxy populations suggest that the masses of BHs are governed by properties of their host dark matter haloes, such as the binding energy and assembly time, at a given halo mass. However, the full picture must be more complex, as galaxy mergers have also been shown to influence the growth of BHs and the impact of AGN. In this study, we investigate this problem through a controlled experiment, using the genetic modification technique to adjust the assembly history of a Milky Way-like galaxy simulated with the EAGLE model. We change the halo assembly time (and hence the binding energy) in the absence of any disruptive merger events, and find little change in the integrated growth of the BH. We attribute this to the angular momentum support provided by a galaxy disc, which reduces the inflow of gas towards the BH and effectively decouples the BH's growth from the halo's properties. Introducing major mergers into the assembly history disrupts the disc, causing the BH to grow ≈4 × more massive and inject feedback that reduces the halo baryon fraction by a factor of ≈2 and quenches star formation. Merger events appear essential to the diversity in BH masses in EAGLE, and we also show that they increase the halo binding energy; correlations between these quantities may therefore be the result of merger events. [ABSTRACT FROM AUTHOR]

Published

2024

2. Galaxy mergers can initiate quenching by unlocking an AGN-driven transformation of the baryon cycle.

Author

Davies, Jonathan J, Pontzen, Andrew, and Crain, Robert A

Subjects

*GALAXY mergers, *DISK galaxies, *SUPERMASSIVE black holes, *INTERSTELLAR medium, *ACTIVE galactic nuclei, *MERGERS & acquisitions

Abstract

We use zoom simulations to show how merger-driven disruption of the gas disc in a galaxy provides its central active galactic nucleus (AGN) with fuel to drive outflows that entrain and expel a significant fraction of the circumgalactic medium (CGM). This in turn suppresses replenishment of the interstellar medium, causing the galaxy to quench up to several Gyr after the merger. We start by performing a zoom simulation of a present-day star-forming disc galaxy with the EAGLE galaxy formation model. Then, we re-simulate the galaxy with controlled changes to its initial conditions, using the genetic modification technique. These modifications either increase or decrease the stellar mass ratio of the galaxy's last significant merger, which occurs at |$z$| ≈ 0.74. The halo reaches the same present-day mass in all cases, but changing the mass ratio of the merger yields markedly different galaxy and CGM properties. We find that a merger can unlock rapid growth of the central supermassive black hole if it disrupts the co-rotational motion of gas in the black hole's vicinity. Conversely, if a less disruptive merger occurs and gas close to the black hole is not disturbed, the AGN does not strongly affect the CGM, and consequently the galaxy continues to form stars. Our result illustrates how a unified view of AGN feedback, the baryon cycle and the interstellar medium is required to understand how mergers and quenching are connected over long time-scales. [ABSTRACT FROM AUTHOR]

Published

2022

3. The gas fractions of dark matter haloes hosting simulated similar to L-star galaxies are governed by the feedback history of their black holes

Author

Davies, Jonathan J., Crain, Robert A., McCarthy, Ian G., Oppenheimer, Benjamin D., Schaye, Joop, Schaller, Matthieu, McAlpine, Stuart, Particle Physics and Astrophysics, Department of Physics, and University of Helsinki, Particle Physics and Astrophysics

Subjects

ACTIVE GALACTIC NUCLEI, AGN FEEDBACK, Astrophysics::High Energy Astrophysical Phenomena, CIRCUMGALACTIC MEDIUM, HOT HALOES, CLUSTER, Astrophysics::Cosmology and Extragalactic Astrophysics, SCALING RELATIONS, 115 Astronomy, Space science, methods: numerical, galaxies: haloes, EAGLE SIMULATIONS, galaxies: formation, STELLAR MASS FUNCTION, GROWTH, HYDRODYNAMICAL SIMULATIONS, galaxies: evolution, Astrophysics::Galaxy Astrophysics

Abstract

We examine the origin of scatter in the relationship between the gas fraction and mass of dark matter haloes hosting present-day similar to L-star central galaxies in the EAGLE simulations. The scatter is uncorrelated with the accretion rate of the central galaxy's black hole (BH), but correlates strongly and negatively with the BH's mass, implicating differences in the expulsion of gas by active galactic nucleus feedback, throughout the assembly of the halo, as the main cause of scatter. Haloes whose central galaxies host undermassive BHs also tend to retain a higher gas fraction, and exhibit elevated star formation rates (SFRs). Diversity in the mass of central BHs stems primarily from diversity in the dark matter halo binding energy, as these quantities are strongly and positively correlated at fixed halo mass, such that similar to L-star galaxies hosted by haloes that are more (less) tightly bound develop central BHs that are more (less) massive than is typical for their halo mass. Variations in the halo gas fraction at fixed halo mass are reflected in both the soft X-ray luminosity and thermal Sunyaev-Zel'dovich flux, suggesting that the prediction of a strong coupling between the properties of galaxies and their halo gas fractions can be tested with measurements of these diagnostics for galaxies with diverse SFRs but similar halo masses.

Published

2019

4. Quenching and morphological evolution due to circumgalactic gas expulsion in a simulated galaxy with a controlled assembly history.

Author

Davies, Jonathan J, Crain, Robert A, and Pontzen, Andrew

Subjects

*INTERSTELLAR medium, *RANDOM number generators, *STAR formation, *GALACTIC evolution, *GALAXY formation, *GALAXIES

Abstract

We examine the influence of dark matter halo assembly on the evolution of a simulated ∼ L ⋆ galaxy. Starting from a zoom-in simulation of a star-forming galaxy evolved with the EAGLE galaxy formation model, we use the genetic modification technique to create a pair of complementary assembly histories: one in which the halo assembles later than in the unmodified case, and one in which it assembles earlier. Delayed assembly leads to the galaxy exhibiting a greater present-day star formation rate than its unmodified counterpart, while in the accelerated case the galaxy quenches at z ≃ 1, and becomes spheroidal. We simulate each assembly history nine times, adopting different seeds for the random number generator used by EAGLE's stochastic subgrid implementations of star formation and feedback. The systematic changes driven by differences in assembly history are significantly stronger than the random scatter induced by this stochasticity. The sensitivity of ∼ L ⋆ galaxy evolution to dark matter halo assembly follows from the close coupling of the growth histories of the central black hole (BH) and the halo, such that earlier assembly fosters the formation of a more massive BH, and more efficient expulsion of circumgalactic gas. In response to this expulsion, the circumgalactic medium reconfigures at a lower density, extending its cooling time and thus inhibiting the replenishment of the interstellar medium. Our results indicate that halo assembly history significantly influences the evolution of ∼ L ⋆ central galaxies, and that the expulsion of circumgalactic gas is a crucial step in quenching them. [ABSTRACT FROM AUTHOR]

Published

2021

5. The quenching and morphological evolution of central galaxies is facilitated by the feedback-driven expulsion of circumgalactic gas.

Author

Davies, Jonathan J, Crain, Robert A, Oppenheimer, Benjamin D, and Schaye, Joop

Subjects

*GALACTIC evolution, *ELLIPTICAL galaxies, *STAR formation, *BINDING energy, *SUPERMASSIVE black holes

Abstract

We examine the connection between the properties of the circumgalactic medium (CGM) and the quenching and morphological evolution of central galaxies in the EAGLE and IllustrisTNG simulations. The simulations yield very different median CGM mass fractions, f CGM, as a function of halo mass, M 200, with low-mass haloes being significantly more gas-rich in IllustrisTNG than in EAGLE. Nonetheless, in both cases scatter in f CGM at fixed M 200 is strongly correlated with the specific star formation rate and the kinematic morphology of central galaxies. The correlations are strongest for ∼ L ⋆ galaxies, corresponding to the mass scale at which AGN feedback becomes efficient. This feedback elevates the CGM cooling time, preventing gas from accreting on to the galaxy to fuel star formation, and thus establishing a preference for quenched, spheroidal galaxies to be hosted by haloes with low f CGM for their mass. In both simulations, f CGM correlates negatively with the host halo's intrinsic concentration, and hence with its binding energy and formation redshift, primarily because early halo formation fosters the rapid early growth of the central black hole (BH). This leads to a lower f CGM at fixed M 200 in EAGLE because the BH reaches high accretion rates sooner, whilst in IllustrisTNG it occurs because the central BH reaches the mass threshold at which AGN feedback is assumed to switch from thermal to kinetic injection earlier. Despite these differences, there is consensus from these state-of-the-art simulations that the expulsion of efficiently cooling gas from the CGM is a crucial step in the quenching and morphological evolution of central galaxies. [ABSTRACT FROM AUTHOR]

Published

2020

6. Feedback from supermassive black holes transforms centrals into passive galaxies by ejecting circumgalactic gas.

Author

Oppenheimer, Benjamin D, Davies, Jonathan J, Crain, Robert A, Wijers, Nastasha A, Schaye, Joop, Werk, Jessica K, Burchett, Joseph N, Trayford, James W, and Horton, Ryan

Subjects

*SUPERMASSIVE black holes, *GALAXIES, *BINDING energy, *GALACTIC evolution, *STAR formation

Abstract

Davies et al. established that for L * galaxies the fraction of baryons in the circumgalactic medium (CGM) is inversely correlated with the mass of their central supermassive black holes (BHs) in the EAGLE hydrodynamic simulation. The interpretation is that, over time, a more massive BH has provided more energy to transport baryons beyond the virial radius, which additionally reduces gas accretion and star formation. We continue this research by focusing on the relationship between the (1) BH masses (M BH), (2) physical and observational properties of the CGM, and (3) galaxy colours for Milky Way-mass systems. The ratio of the cumulative BH feedback energy over the gaseous halo binding energy is a strong predictor of the CGM gas content, with BHs injecting significantly higher than the binding energy resulting in gas-poor haloes. Observable tracers of the CGM, including |$\rm {C\, \small{IV}}$|⁠ , |$\rm {O\, \small{VI}}$|⁠ , and |${\rm {H\, \small{I}}}$| absorption line measurements, are found to be effective tracers of the total z ∼ 0 CGM halo mass. We use high-cadence simulation outputs to demonstrate that BH feedback pushes baryons beyond the virial radius within 100 Myr time-scales, but that CGM metal tracers take longer (0.5–2.5 Gyr) to respond. Secular evolution of galaxies results in blue, star-forming or red, passive populations depending on the cumulative feedback from BHs. The reddest quartile of galaxies with M * = 1010.2−10.7 M⊙ (median u − r  = 2.28) has a CGM mass that is 2.5 times lower than the bluest quartile (u − r  = 1.59). We propose observing strategies to indirectly ascertain f CGM via metal lines around galaxies with measured M BH. We predict statistically detectable declines in |$\rm {C\, \small{IV}}$| and |$\rm {O\, \small{VI}}$| covering fractions with increasing M BH for central galaxies with M * = 1010.2−10.7M⊙. [ABSTRACT FROM AUTHOR]

Published

2020

7. The gas fractions of dark matter haloes hosting simulated ∼L⋆ galaxies are governed by the feedback history of their black holes.

Author

Davies, Jonathan J, Crain, Robert A, McCarthy, Ian G, Oppenheimer, Benjamin D, Schaye, Joop, Schaller, Matthieu, and McAlpine, Stuart

Subjects

*BINARY black holes, *DARK matter, *GALAXIES, *ACTIVE galactic nuclei, *SOFT X rays, *HEAT flux, *BLACK holes

Abstract

We examine the origin of scatter in the relationship between the gas fraction and mass of dark matter haloes hosting present-day ∼ L ⋆ central galaxies in the EAGLE simulations. The scatter is uncorrelated with the accretion rate of the central galaxy's black hole (BH), but correlates strongly and negatively with the BH's mass, implicating differences in the expulsion of gas by active galactic nucleus feedback, throughout the assembly of the halo, as the main cause of scatter. Haloes whose central galaxies host undermassive BHs also tend to retain a higher gas fraction, and exhibit elevated star formation rates (SFRs). Diversity in the mass of central BHs stems primarily from diversity in the dark matter halo binding energy, as these quantities are strongly and positively correlated at fixed halo mass, such that ∼ L ⋆ galaxies hosted by haloes that are more (less) tightly bound develop central BHs that are more (less) massive than is typical for their halo mass. Variations in the halo gas fraction at fixed halo mass are reflected in both the soft X-ray luminosity and thermal Sunyaev–Zel'dovich flux, suggesting that the prediction of a strong coupling between the properties of galaxies and their halo gas fractions can be tested with measurements of these diagnostics for galaxies with diverse SFRs but similar halo masses. [ABSTRACT FROM AUTHOR]

Published

2019