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The Diversity of Assembly Histories Leading to Disc Galaxy Formation in a ΛCDM Model

Published online by Cambridge University Press:  06 November 2017

Andreea S. Font*
Affiliation:
Astrophysics Research Institute, Liverpool John Moores University, 146 Brownlow Hill, Liverpool, L3 5RF, UK
Ian G. McCarthy
Affiliation:
Astrophysics Research Institute, Liverpool John Moores University, 146 Brownlow Hill, Liverpool, L3 5RF, UK
Amandine M. C. Le Brun
Affiliation:
IRFU, CEA, Université Paris-Saclay, F-91191 Gif-sur-Yvette, France Université Paris Diderot, AIM, Sorbonne Paris Cité, CEA, CNRS, F-91191 Gif-sur-Yvette, France
Robert A. Crain
Affiliation:
Astrophysics Research Institute, Liverpool John Moores University, 146 Brownlow Hill, Liverpool, L3 5RF, UK
Lee S. Kelvin
Affiliation:
Astrophysics Research Institute, Liverpool John Moores University, 146 Brownlow Hill, Liverpool, L3 5RF, UK
*
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Abstract

Disc galaxies forming in a LambdaCDM cosmology often experience violent mergers. The fact that disc galaxies are ubiquitous suggests that quiescent histories are not necessary. Modern cosmological simulations can now obtain realistic populations of disc galaxies, but it is still unclear how discs manage to survive massive mergers. Here we use a suite of hydrodynamical cosmological simulations to elucidate the fate of discs encountering massive mergers. We follow the changes in the post-merger disc-to-total ratios (D/T) of simulated galaxies and examine the relations between their present-day morphology, assembly history and gas fractions. We find that approximately half of present-day disc galaxies underwent at least one merger with a satellite more massive the host's stellar component and a third had mergers with satellites three times as massive. These mergers lead to a sharp, but often temporary, decrease in the D/T of the hosts, implying that discs are usually disrupted but then quickly re-grow. To do so, high cold gas fractions are required post-merger, as well as a relatively quiescent recent history (over a few Gyrs before z = 0). Our results show that discs can form via diverse merger pathways and that quiescent histories are not the dominant mode of disc formation.

Type
Research Article
Copyright
Copyright © Astronomical Society of Australia 2017 

1 INTRODUCTION

A long-standing problem in galaxy formation has been reconciling the abundance of disc galaxies observed in the nearby Universe (e.g., Weinmann et al. Reference Weinmann, van den Bosch, Yang and Mo2006; Park et al. Reference Park, Choi, Vogeley, Gott and Blanton2007) with the high rate of supposedly disc-destroying mergers predicted in ΛCDM cosmologies (Toth & Ostriker Reference Toth and Ostriker1992; Stewart et al. Reference Stewart, Bullock, Wechsler, Maller and Zentner2008; Boylan-Kolchin et al. Reference Boylan-Kolchin, Springel, White and Jenkins2010). For example, the majority (~70%) of Milky Way-mass haloes are predicted to undergo mergers with total mass ratios M sat : M host > 1 : 10 (Stewart et al. Reference Stewart, Bullock, Wechsler, Maller and Zentner2008), where the total masses include baryons and dark matter. Although considered ‘minor’ from a total mass ratio perspective, a subhalo with a tenth of the mass of the Milky Way’s total halo mass has a mass that is roughly twice the mass of the present-day stellar disc. From the central galaxy’s perspective, therefore, such mergers are clearly significant. Combining the merger rates for systems in the 1 : 10 mass range with collisionless estimates of merger-induced disc heating rates, one may conclude that very few discs should survive down to the present day. This is in evident contradiction with local observations, which show that ~70% of normal galaxies with stellar masses ~1010 − 10.5M have significant disc components (e.g., Park et al. Reference Park, Choi, Vogeley, Gott and Blanton2007; Kelvin et al. Reference Kelvin2014).

The solution to this problem is to discard the paradigm of quiescent formation history of disc galaxies, which is now generally agreed to be obsolete. Gas physics is commonly invoked to reconcile present-day disc morphologies with active merger histories. Gas-dynamical simulations suggest an interplay of various mechanisms such as feedback and gas-rich mergers (Barnes Reference Barnes2002; Springel & Hernquist Reference Springel and Hernquist2003, Reference Springel and Hernquist2005; Robertson et al. Reference Robertson, Bullock, Cox, Di Matteo, Hernquist, Springel and Yoshida2006; Hopkins et al. Reference Hopkins, Cox, Younger and Hernquist2009; Scannapieco et al. Reference Scannapieco, White, Springel and Tissera2009; Brooks et al. Reference Brooks2011; Brook et al. Reference Brook, Stinson, Gibson, Roškar, Wadsley and Quinn2012), accretion of gas through cold flows (e.g., Governato et al. Reference Governato2009) and/or cooling of the hot phase (e.g., Moster et al. Reference Moster, Macciò, Somerville, Naab and Cox2012). The presence of cold gas prior to the merger can act to absorb (and later radiate) some of the unbinding energy injected during the merger, while any cold gas remaining after the merger, plus any new cold gas that is accreted post-merger, can lead to re-growth of the disc.

Still needed is a more quantitative assessment of the role of gas in alleviating the effect of mergers. Using controlled and idealised hydrodynamical simulations of galaxy collisions, Hopkins et al. (Reference Hopkins, Cox, Younger and Hernquist2009) found that the survivability of discs was strongly correlated with the initial gas fraction (defined as f gas, bM gas/M (gas + stars)). Results of controlled hydrodynamical simulations, where the gas fraction is treated as a free parameter, show that galaxy discs usually re-form when f gas, b ⩾ 80–90% (e.g., Robertson et al. Reference Robertson, Bullock, Cox, Di Matteo, Hernquist, Springel and Yoshida2006; Hopkins et al. Reference Hopkins, Cox, Younger and Hernquist2009). These values appear to be in reasonable agreement with observational gas fraction estimates at z = 2 (Erb et al. Reference Erb, Steidel, Shapley, Pettini, Reddy and Adelberger2006). Note, however, that at redshifts 1 < z < 2 (where the merger activity is still significant), the cold gas fractions can be as low as 50% (e.g., Tacconi et al. Reference Tacconi2013). Semi-analytical models (e.g., De Lucia, Kauffmann, & White Reference De Lucia, Kauffmann and White2004; Bower et al. Reference Bower, Benson, Malbon, Helly, Frenk, Baugh, Cole and Lacey2006; Font et al. Reference Font2008; Somerville et al. Reference Somerville, Hopkins, Cox, Robertson and Hernquist2008) obtain similar results, although the results are known to depend on the detailed implementation of physical prescriptions (Hopkins et al. Reference Hopkins2010). Since potentially disc-damaging mergers are expected to occur frequently down to z ≃ 1 (Stewart et al. Reference Stewart, Bullock, Wechsler, Maller and Zentner2008; Boylan-Kolchin et al. Reference Boylan-Kolchin, Springel, White and Jenkins2010), it is important to evaluate in a self-consistent way the relation between cold gas fractions, disc formation, and the merger history of galaxies. This can be achieved with cosmological hydrodynamical simulations.

To date, studies based on zoomed cosmological simulations (typically of small numbers of systems) have shown mixed results, at least in terms of the interpretation of how discs persist to the present day. Some studies support the scenario in which discs form as a result of gas-rich (f gas, b > 0.8) mergers (Brook et al. Reference Brook, Richard, Kawata, Martel and Gibson2007; Guedes et al. Reference Guedes, Callegari, Madau and Mayer2011), although in these simulations, the major mergers are restricted to occur at high redshift. Other studies show that discs can form at low redshift when gas fractions are much lower. For example, Governato et al. (Reference Governato2009) found a large disc growing after a major (1:1) merger at z ~ 0.9, when f gas, b < 0.25. They argue that in this case an important role is played by cold flow accretion along filaments (Kereš et al. Reference Kereš, Katz, Weinberg and Davé2005, Reference Kereš, Katz, Fardal, Davé and Weinberg2009; Dekel, Sari, & Ceverino Reference Dekel, Sari and Ceverino2009), a process which is not included in idealised galaxy merger simulations. A disc galaxy is also shown to form after z < 1 in a major merger in the simulation of Brook et al. (Reference Brook, Stinson, Gibson, Roškar, Wadsley and Quinn2012), although this system has a lower mass than a typical disc galaxy.

Ideally, one would like to tackle this problem using large, statistically representative samples of galaxies simulated at high resolution with hydrodynamics and in the full cosmological context. With the advent of large-volume simulation campaigns such as Galaxies-Intergalactic Medium Interaction Calculations (GIMIC) (Crain et al. Reference Crain2009) and more recently Illustris (Vogelsberger et al. Reference Vogelsberger2014), EAGLE (Schaye et al. Reference Schaye2015), and Horizon-AGN (Kaviraj et al. Reference Kaviraj2016), this is now a possibility. A major success of these campaigns is their ability to produce large samples of disc galaxies, at least in qualitative agreement with the observations. From this point of view, the problem appears to be ‘solved’, in that the ubiquity of disc galaxies is consistent with our current theoretical paradigm for structure formation (i.e., ΛCDM). However, it is nevertheless still important to elucidate the physics that allows galaxies to retain (or re-form) their discs; analysis of large statistical samples of simulated galaxies should help clarify the somewhat confused picture that has emerged from studies based on zoomed simulations of small numbers of systems. Furthermore, it has not yet been demonstrated that the predicted distribution of morphologies from simulations actually agrees with that of real galaxies in a quantitative sense. We will make such a comparison here. We will also quantify the fraction of galaxies that (re-)form their discs after mergers versus those that form more quiescently. For those disc galaxies that form post-mergers, we also investigate the various pathways that lead to the formation of their discs.

We use the GIMIC simulations to explore these topics. As demonstrated in a number of previous studies, GIMIC is successful at forming large numbers of disc galaxies that match a broad number of observed scaling relations and galaxy properties. Namely, the simulations produce reasonably realistic ~L* disc galaxies that match the Tully–Fisher relation, the rotation curves, sizes, and star formation efficiencies of low-mass disc galaxies (McCarthy et al. Reference McCarthy, Schaye, Font, Theuns, Frenk, Crain and Dalla Vecchia2012b), the cold gas fraction–stellar mass and gas-phase metallicity–stellar mass relations (De Rossi et al. Reference De Rossi, Theuns, Font and McCarthy2015), the number, alignment and the spatial distribution of their satellite galaxies (Deason et al. Reference Deason2011; Font et al. Reference Font, McCarthy, Crain, Theuns, Schaye, Wiersma and Dalla Vecchia2011), the surface brightness, and metallicity distributions of the stellar haloes in the Milky Way, M31 and other nearby disc galaxies (Font et al. Reference Font, McCarthy, Crain, Theuns, Schaye, Wiersma and Dalla Vecchia2011; McCarthy et al. Reference McCarthy, Font, Crain, Deason, Schaye and Theuns2012a) and the X-ray scaling relations for normal disc galaxies (Crain et al. Reference Crain, McCarthy, Frenk, Theuns and Schaye2010). Therefore, these simulations are well-suited to address the topics in our study.

A potential drawback of these simulations is that they do not include a physical prescription for AGN feedback, as has been found to be important in more recent simulations such as EAGLE (Schaye et al. Reference Schaye2015; Crain et al. Reference Crain2015) or in the study of Pontzen et al. (Reference Pontzen, Tremmel, Roth, Peiris, Saintonge, Volonteri, Quinn and Governato2017). However, this is not a serious omission for the mass range we consider here (stellar masses of ~1010 M). We demonstrate this later (Appendix A), where we compare the stellar mass−halo mass relations, size−mass relations, and distribution of morphologies predicted by GIMIC and EAGLE, showing that they are very similar for all but the most massive galaxies. The realism of our simulated disc galaxies is tested further by comparing their morphologies with those derived from recent observations (see Section 3 and Appendix B).

This paper is organised as follows. In Section 2, we summarise the simulations and sample selection. In Section 3, we compare the morphologies of the simulated galaxy population with observational data. In Section 4, we calculate halo–halo and subhalo-galaxy merger rates and show the effects of mergers of different mass ratios on the simulated discs. In Section 5, we investigate the role played in the growth of stellar discs by cold gas fractions and merger histories and quantify the various formation histories of present-day disc galaxies. In Section 6, we discuss the disc re-growth scenario in the context of some observations. Finally, the main conclusions are summarised in Section 7.

2 SIMULATIONS AND SAMPLE PROPERTIES

2.1. Simulation description

In this study, we use the two highest resolution simulations from the GIMIC suite of simulation (see McCarthy et al. Reference McCarthy, Schaye, Font, Theuns, Frenk, Crain and Dalla Vecchia2012b). Following the GIMIC terminology (Crain et al. Reference Crain2009), these regions are called −2σ and 0σ, which indicates that the overdensities of the two regions at z = 1.5 are −2 and 0, respectively, of the standard deviation from the cosmic mean σ (here, σ is the RMS mass fluctuation on a scale of 18 h−1 Mpc). The two roughly spherical regions, with radii of ~18h −1Mpc, were extracted from the dark matter-only Millennium simulation (Springel et al. Reference Springel2005) and re-simulated from z = 127 to z = 0 with gas dynamics. The remaining Millennium volume (500 h −1 Mpc on a side) was also simulated but at lower resolution and with purely collisionless dynamics. The cosmological parameters used in these runs are Ωm = 0.25, ΩΛ = 0.75, Ωb = 0.045, n s = 1 (the spectral index of the primordial power spectrum), σ8 = 0.9 (the RMS amplitude of linear mass fluctuations on a 8 h −1 Mpc scale at z = 0), H0 = 100~h~kms−1Mpc−1, and h = 0.73.

The increased resolution enables us to better resolve the structure of galaxy discs and the high-mass end of substructure mass function, M sat ⩾ 108 − 9~M. The masses of dark matter particles are 6.63 × 106~h −1~M, those of gas particles are 1.46 × 106~h −1~M, and the gravitational softening is 0.5 h −1 kpc. This is comparable with the resolutions of the recent Illustris (Vogelsberger et al. Reference Vogelsberger2014) and EAGLE (Schaye et al. Reference Schaye2015; Crain et al. Reference Crain2015) main box simulations. The dark matter resolution is similar to other large-scale (but dark matter only) cosmological simulations, such as Millennium II (Boylan-Kolchin et al. Reference Boylan-Kolchin, Springel, White, Jenkins and Lemson2009), which enables us to perform a comparison with their results.

The simulations were run with the TreePM-SPH code Gadget-3 (last described by Springel et al. Reference Springel2005). Below we only summarise the subgrid physics prescriptions in this code and direct the reader to the referenced papers for further details. The code includes prescriptions for star formation (Schaye & Dalla Vecchia Reference Schaye and Dalla Vecchia2008), metal-dependent radiative cooling in the presence of a global UV/X-ray background (Wiersma, Schaye, & Smith Reference Wiersma, Schaye and Smith2009a), stellar mass loss and chemical evolution (Wiersma et al. Reference Wiersma, Schaye, Theuns, Dalla Vecchia and Tornatore2009b), and a kinetic supernova feedback model (Dalla Vecchia & Schaye Reference Dalla Vecchia and Schaye2008).

The simulations lack the resolution to resolve the Jeans scales of the cold (T < 104 K), dense gas phase (n H ≫ 0.1 cm−3) of the ISM. An effective equation of state is instead imposed, in order to approximate the effects of feedback and turbulence in the ISM and to prevent artificial fragmentation for gas that is above a fixed density threshold of n H > 0.1 cm−3. Gas particles on the equation of state are allowed to convert into star particles (stochastically) at a pressure-dependent rate that reproduces the observed Kennicutt–Schmidt law (Kennicutt Reference Kennicutt1998), by construction. Radiative cooling is computed on an element-by-element basis, following 11 species relevant to cooling. Feedback associated with star formation is modelled using a kinetic implementation (i.e., neighbouring gas particles are given a velocity kick), with an initial wind velocity of 600 km s−1 and a mass-loading parameter (i.e., the ratio of the mass of gas given a velocity kick to that turned into newly formed star particles), η, set to 4. This corresponds to using approximately 80% of the total energy available from supernovae for a Chabrier (Reference Chabrier2003) IMF, which is assumed in the simulation. This choice of parameters results in a good match to the peak of the star formation rate history of the Universe (Crain et al. Reference Crain2009; Schaye et al. Reference Schaye2010).

As described in the Introduction, these simulations have achieved a number of notable successes. At the same time, it is important to acknowledge their shortcomings. Most notably, because they neglect feedback from AGN, the simulations suffer from overcooling in the most massive galaxies. As shown by Crain et al. (Reference Crain2009), the simulations fail to reproduce the bright end of the galaxy stellar mass function, in that they predict too many massive galaxies compared to what is observed. However, in the present study, we focus on galaxies with z = 0 stellar masses of M star ~ 1010 M, which is the typical mass of normal disc galaxies today (Kelvin et al. Reference Kelvin2014). The simulations also reproduce many of the observed correlations of lower mass galaxies (see McCarthy et al. Reference McCarthy, Schaye, Font, Theuns, Frenk, Crain and Dalla Vecchia2012b), but we focus on systems with M star ~ 1010 M as they are the best resolved disc galaxies in our simulations. We reiterate that in Appendix A we show the galaxies used in this study agree on a number of key relations and properties with galaxies of similar mass in the EAGLE simulations (which better reproduce the full galaxy stellar mass function), indicating that AGN feedback does not play an important role for the galaxies under consideration.

2.2. Identifying subhaloes and constructing merger histories

Haloes are identified using a standard friends-of-friends (FoF) algorithm with a linking length of b = 0.2 times the mean inter-particle separation, run on the dark matter particles. Baryons are included by linking in the nearest baryon particle (gas or star) to each FoF dark matter particle. All groups with a minimum of 20 particles are retained for further analysis. We then remove all haloes that are not gravitationally self-bound by performing an unbinding calculation with SUBFIND (Springel et al. Reference Springel, White, Tormen and Kauffmann2001; Dolag et al. Reference Dolag, Borgani, Murante and Springel2009).

Simple merger trees are constructed for the main haloes that satisfy our mass selection criterion (see Section 2.3 below). We trace the main progenitors of the z = 0 systems back to z ≃ 5, before the emergence of any discs. The procedure for tracing back the main progenitor of the central halo is as follows. We select all dark matter particles within r 200 of the main halo at z = 0 and identify them at earlier redshifts using their unique IDs. At each redshift output, we determine whether these particles are bound gravitationally to any structure. The main progenitor at a given redshift is taken to be the subhalo that contains the largest fraction of the dark matter particles selected at z = 0. The algorithm uses only the dark matter particles, as they constitute most of the mass of a system and, unlike baryonic particles, are not directly affected by pressure forces. Having identified the main progenitor, we then follow forward in time from z ≃ 5 all (sub)haloes that eventually merge with the main progenitor’s FoF group by the present day.

2.3. Galaxy sample

We kinematically classify the galaxies into disc- and spheroid-dominated categories based on the rotational angular momentum, J z, of bound star particles within 20 kpc (we use the most bound particle to identify the galaxy centre). To assign particles to the disc component, we use a simple cut of J z/J circ ⩾ 0.75, where J circ is the angular momentum of a star particle on a co-rotating circular orbit with the same energy. In our definition, disc galaxies are those with a kinematical disc to total ratio D/T ⩾ 0.3; however, the main conclusions of this paper do not change by choosing a higher limit of D/T or by adopting a different cut in the angular momentum required for disc assignment. In Section 3, we discuss the correspondence between the 3D kinematic D/T diagnostic that we employ throughout the present study and the apparent (2D) morphology that one would more typically derive for observed galaxies.

As in our previous studies (Font et al. Reference Font, McCarthy, Crain, Theuns, Schaye, Wiersma and Dalla Vecchia2011; McCarthy et al. Reference McCarthy, Font, Crain, Deason, Schaye and Theuns2012a; McCarthy et al. Reference McCarthy, Schaye, Font, Theuns, Frenk, Crain and Dalla Vecchia2012b), we do not impose any constraints on the merger histories of galaxies, as we also want to follow the formation of disc galaxies with non-quiescent merger histories (in addition to galaxies that contain no significant disc component, to investigate why). We select only galaxies in the range of total stellar mass 9.7 ⩽ log(M star, tot/M) ⩽ 10.3 (median stellar mass of ≃ 109.9 M). This mass range is chosen in order to minimise the mass-dependence in the merger rates results and also to avoid issues with overcooling at higher masses (see McCarthy et al. Reference McCarthy, Schaye, Font, Theuns, Frenk, Crain and Dalla Vecchia2012b). For reference, the upper M star, tot limit is somewhat smaller than the estimated stellar mass of the Milky Way, M $_{\rm star, \rm tot,{\rm MW}} \simeq 3.6-5.4 \times 10^{10}$ M (Flynn et al. Reference Flynn, Holmberg, Portinari, Fuchs and Jahreiß2006; McMillan Reference McMillan2011). The median halo mass M 200(z = 0) (i.e., the mass enclosed within a sphere containing an average density ≃ 200 times the present-day critical density) is ≃ 1011.7 M, is also somewhat lower than the typical 1–2 × 1012 M inferred for the Milky Way (Evans & Wilkinson Reference Evans and Wilkinson2000; Battaglia et al. Reference Battaglia2005; Karachentsev & Kashibadze Reference Karachentsev and Kashibadze2006; Li & White Reference Li and White2008; Guo et al. Reference Guo, White, Li and Boylan-Kolchin2010), although some recent studies estimate a lower total mass of the Milky Way, ~5–10 × 1011 M (Xue et al. Reference Xue2008; Deason et al. Reference Deason2012; Gibbons, Belokurov, & Evans Reference Gibbons, Belokurov and Evans2014). Therefore, our simulated galaxy sample is more representative of slightly sub-L* galaxies. Note that even within this mass range, we still have a large sample of 107 high-resolution simulated galaxies. As already mentioned, this mass range also encompasses the typical stellar mass of disc galaxies observed in the local Universe (Kelvin et al. Reference Kelvin2014).

Finally, we note that the sample combines systems from both the −2σ and 0σ regions since galaxy properties do not show any significant dependency on very large-scale environment (see also Crain et al. Reference Crain2009; Font et al. Reference Font, McCarthy, Crain, Theuns, Schaye, Wiersma and Dalla Vecchia2011).

3 PRESENT-DAY MORPHOLOGIES: COMPARISON WITH OBSERVATIONS

Before proceeding to our main analysis, we first examine some additional relevant tests of the realism of the present-day discs in the simulations (as mentioned in the Introduction, the simulated galaxies match a broad range of global scaling properties of present-day galaxies). Specifically, here we focus on the present-day morphologies of the simulated galaxies and compare them, in a like-with-like fashion, to observational data, demonstrating that the simulated galaxy population has a realistic distribution of morphologies.

We first compare to the observed morphologies of local galaxies in the GAMA survey. From the GAMA Data Release 2 databaseFootnote 1 , we select local galaxies with 0.07 < z < 0.12 (median z ≈ 0.10) and that lie in the same stellar mass range as the simulated galaxies (i.e., 9.7 < log10[M */M] < 10.3) and that have had single Sérsic models fitted to their surface brightness profiles in the various GAMA bands by Kelvin et al. (Reference Kelvin2012). Applying these selection criteria yields a sample of approximately 4 800 galaxies. We focus on the Sérsic index, which governs the rate of the fall off of light with radius and therefore characterises the morphology of a galaxy. More details about the construction of synthetic GAMA r-band images and about the Sérsic index model fitting are given in Appendix B.

In Figure 1, we compare the predicted (solid thick black curve) and observed (solid thick red curve) distributions of the r-band Sérsic index. Overall, the simulated distribution is quite similar to that of the GAMA sample, both showing strong peaks in the distribution near a Sérsic index of 1 (which corresponds to an exponential disc profile). In detail, the peak of simulated distribution occurs at a slightly higher value than that of the GAMA sample. Nevertheless, the agreement is impressive considering that no attempt was made to calibrate the GIMIC simulations on any aspect of the morphology of the galaxies.

Figure 1. Comparison of the distribution of Sérsic indices from GIMIC (thick solid black curve) with that derived from the analysis of local (0.07 < z < 0.12) GAMA galaxies, selected to be in the same stellar mass range applied to the simulated galaxies (thick solid red curve; Kelvin et al. Reference Kelvin2012). The error bars correspond to the Poisson errors, derived by taking the square root of the number of galaxies in each Sérsic index bin. To derive the Sérsic indices of the simulated galaxies, we create synthetic GAMA-like images of the simulated galaxies, accounting for the effects of the SDSS telescope point spread function and Poisson noise (due to both the galaxy and the sky; see Appendix B for further details). The thin short-dashed, long-dashed, and dot-dashed black curves show the effects of switching on/off the modelling of Poisson noise and the point spread function. The simulated galaxy population has a qualitatively similar distribution of morphologies to that of the observed GAMA sample.

The thin black curves show the effects of turning on/off the modelling of the noise and the point spread function. Including these effects does not change the qualitative picture, but it does affect the derived distribution in a quantitative sense, in that the resulting distribution is somewhat broader and the peak is shifted to slightly larger values of the Sérsic index when realistic noise and smoothing is incorporated into the analysis.

It is of interest to examine briefly the correspondence between the kinematic D/T morphological indicator that we use for the remainder of the paper with the apparent (2D) morphology, as characterised by the Sérsic index derived from the image modelling analysis above. In Figure 2, we examine the relation between these two quantities at z = 0. Although there is significant scatter, there is also clearly a strong anti-correlation between the parameters (the Spearman rank correlation coefficient is r = −0.49). Our fiducial threshold of D/T = 0.3 used to separate galaxies into disc- or spheroid-dominated systems also roughly delineates systems into (relatively speaking) low and high values of the Sérsic index. Thus, in a broad sense, there is a good correlation between the 3D kinematics and the 2D (light-weighted) appearance of galaxies, which is expected and reassuring (see also Scannapieco et al. Reference Scannapieco, Gadotti, Jonsson and White2010; Obreja et al. Reference Obreja, Stinson, Dutton, Macciò, Wang and Kang2016). We note that we use the (3D) kinematic D/T as our indicator of the morphology because it is a more physical quantity linked to the energetics of the system and does not depend on complicating factors such as projection effects and the mapping between light and mass (which depends on age, metallicity, etc.).

Figure 2. The z = 0 relation between the kinematic D/T and the apparent (2D) morphology, as characterised by the Sérsic index derived from synthetic images of GIMIC galaxies. Although significant scatter is present, a strong anti-correlation is clearly visible, such that high values of D/T correspond to low values of the Sérsic index. The vertical dotted line at D/T = 0.3 corresponds to our fiducial dividing line between disc-dominated and bulge-dominated systems, which also roughly delineates the systems into high and low values of the Sérsic index.

As shown above, many of the simulated and observed galaxies in this stellar mass range have a broadly disky appearance, in that they are typically characterised by Sérsic indices of ~1. One can go a step further and ask whether the detailed distribution of scale-heights (z 0) and scale-lengths (h R ) of (thick + thin) components of the simulated discs are also reasonable. For this test, we compare with measurements of these quantities of similar-mass nearby late-type galaxies from Kregel, van der Kruit, & de Grijs (Reference Kregel, van der Kruit and de Grijs2002) and Yoachim & Dalcanton (Reference Yoachim and Dalcanton2006).

For a given simulated galaxy, we compute the scale-height and -length in the following manner (which is meant to roughly mimic the observational analysis). We first rotate the galaxy into an edge-on configuration, by aligning the total angular momentum of the stars (within a 20 kpc aperture) with the z-axis of the simulation box. We then select the disc particles and produce two-dimensional i-band surface brightness maps in cylindrical coordinates (R, z), with R being the projected radius along the disc. Following the observational studies that we compare to, we fit a two-dimensional parametric model of the following form to the maps:

(1) $$\begin{equation} L(R,z)=L_0\exp ^{-R/h_R}f(z), \ \ \, \end{equation}$$

where L 0 is the central luminosity density and f(z) is the generalised sech2/N (Nz/z 0) vertical distribution (N = 1 for the thin + thick disc; see Yoachim & Dalcanton Reference Yoachim and Dalcanton2006).

Figure 3 shows the present-day disc scale-heights and scale-lengths versus the maximum rotation speeds V rot of the sample disc galaxies, in comparison with similar measurements in nearby sub-L* disc galaxies of Kregel et al. (Reference Kregel, van der Kruit and de Grijs2002) and Yoachim & Dalcanton (Reference Yoachim and Dalcanton2006). The typical values for the simulations of z 0 ~ 1 kpc and h R ~ 4 kpc are in reasonably good agreement with the observational data (see also the data of Bizyaev & Mitronova Reference Bizyaev and Mitronova2002). However, we caution that the comparison to the scale-heights may be somewhat influenced by the force resolution of the simulation (the Plummer-equivalent softening is 500~h −1 pc, represented by the dashed line in Figure 3) and the simplified treatment of the ISM (the Jeans length of the equation of state is ~1 kpc), which will effectively prevent the formation of very thin discs in the simulations. Nevertheless, it is encouraging that the structural properties are similar to observed nearby galaxies, which gives us some confidence that the disc component in the simulated galaxies will react to mergers, etc. in a realistic fashion.

Figure 3. Comparison of disc scale-heights (Left) and scale-lengths (Right) of simulated galaxies in GIMIC (black circles) with those measured for nearby galaxies by Kregel et al. (Reference Kregel, van der Kruit and de Grijs2002) and Yoachim & Dalcanton (Reference Yoachim and Dalcanton2006) (red and blue diamonds) versus the maximum rotation speeds V rot. The dashed horizontal line shows the (Plummer equivalent) force softening of the simulations. Over the range of masses considered here, the simulated galaxies have broadly realistic sizes.

3.1. Summary of comparison to observations

We have shown that the simulated galaxy population that we examine in this study has a reasonably realistic distribution of morphologies, as characterised by the Sérsic index and effective radii and the scale-lengths and scale-heights of the disc component. The sample is therefore well-suited to address the question of the origin of present-day morphologies and elucidating its connection to the assembly history of galaxies.

4 MERGERS: PROBABILITIES AND EFFECTS

In this section, we revisit the likelihood of mergers of different mass ratios in a ΛCDM cosmology. We demonstrate that most L * galaxies (M star ~ 1010M) are expected to experience a collision with mass ratio ~1 : 1 (defined in terms of the ratio of total satellite mass to central galaxy stellar mass) since z ~ 2. We further show that such mergers are generally expected to induce large morphological transformations.

4.1. Merger probabilities

4.1.1. By the ratio of total halo masses

Several studies have already calculated the merger rates of Milky Way-mass dark matter haloes using N-body cosmological simulations (e.g., Stewart et al. Reference Stewart, Bullock, Wechsler, Maller and Zentner2008 and Boylan-Kolchin et al. Reference Boylan-Kolchin, Springel, White and Jenkins2010). In particular, the Millennium II simulations used by Boylan-Kolchin et al. (Reference Boylan-Kolchin, Springel, White and Jenkins2010) have many similarities with GIMIC, for example, the identical cosmologies and the similar mass resolutions. Although smaller in volume, our gas-dynamical simulations take into account additional mechanisms associated with the existence of stellar discs. We first briefly examine halo–halo mergers to provide a baseline for comparison with dark matter only studies.

Figure 4 shows the cumulative fraction, f, of all the main dark matter haloes in our sample that undergo mergers with mass ratios XM sat, max/M 200(z = 0) (where M sat, max is the maximum mass of a dark matter subhalo over its whole history and M 200 is the virial mass of the host halo at z = 0) greater than several threshold values. The results are quite similar to those of Boylan-Kolchin et al. (Reference Boylan-Kolchin, Springel, White and Jenkins2010), who find ≃ 55% of haloes had mergers >1 : 10 and >30% had mergers >1 : 6–7. As already noted, the masses of these merging systems are 2–3 times more massive than the mass of a putative Milky Way disc embedded in these dark matter haloes. Therefore, on the basis of halo–halo merger probabilities, one may conclude that a significant fraction of dark matter haloes experience mergers which are potentially damaging to the embedded discs from z = 2 to the present. Moreover, some haloes have multiple events of this kind (Stewart et al. Reference Stewart, Bullock, Wechsler, Maller and Zentner2008; Boylan-Kolchin et al. Reference Boylan-Kolchin, Springel, White and Jenkins2010).

Figure 4. The cumulative fraction of haloes (median M 200 = 1011.7 M) which have mergers with mass ratios XM sat, max/M 200(z = 0) > 0.01 (red), >0.03 (orange), >0.10 (green), and >0.15 (blue).

4.1.2. By the ratio of satellite to central galaxy mass

The merger probabilities involving (sub)haloes and the central galaxy are more directly relevant to the question of the survivability of galaxy discs than the halo-halo merger rates. Figure 5 shows the cumulative fraction of galaxies that undergo mergers with mass ratios XM sat/M star, host > 0.5, 1, 3, 10. We explore the importance of mass loss of the satellite due to tidal stripping since the time of accretion onto the main halo, by computing the mass ratio both at the time of accretion (defined as when the satellite first crosses r 200(z) of the main halo) and when it first comes within 20 kpc (physical) of the central galaxy (i.e., roughly the size of a typical galaxy disc, around which tidal interactions are the strongest). These two cases are represented by the solid and dashed curves, respectively.

Figure 5. The cumulative fraction of galaxies that have mergers with mass ratios: XM sat/M star, host > 10 (blue), >3 (green), 1.0 (orange), and >0.5 (red). Solid lines correspond to the case when the satellite crossed r 200(z) and dashed lines when the satellite crossed a fixed physical radius of 20 kpc.

When using the mass ratio at the time of accretion to calculate the probabilities, it is clear that major mergers are quite common. For example, nearly all galaxies are expected to have had at least one merger where the incoming satellite is of comparable mass (1:1) to the central galaxy (in terms of its stellar mass). However, the picture changes significantly when one defines the merger mass ratio using the satellite mass just prior to the collision (here evaluated at 20 kpc). For example, when tidal stripping is taken into account, ~20–30% fewer galaxies experience minor mergers (X > 0.5–1) since z = 2 and significantly fewer galaxies, about a factor of three fewer, experience mergers with X > 10. The sharp decrease in the galaxy merger probabilities with increasing mass ratio X illustrates that more massive satellites are more strongly affected by tidal stripping. Overall, our results suggest that semi-analytic models that neglect this effect will markedly overestimate the merger rates of galaxies and possibly also the damage induced to the embedded discs (see also Wilman et al. Reference Wilman, Fontanot, De Lucia, Erwin and Monaco2013).

Nevertheless, tidal stripping by itself is not a solution to the disc abundance problem, since the rate of disc-damaging mergers is still high even after its effect is taken into account. For example, the dashed lines in Figure 5 show that since z = 2 the majority (~60%) of galaxies in the sample undergo mergers >3M star, host and ~80% undergo mergers >M star, host. As we show below, most of these mergers are expected to induce significant morphological changes to their hosts. Therefore, disc-damaging mergers are still expected to be frequent in a hierarchical scenario, in qualitative agreement with previous dark matter only results.

4.2. The effect of mergers on galaxy discs

Having calculated the likelihood of mergers of different mass ratios, we now assess the effect that these mergers have on the disc, by evaluating the change they induce in the D/T ratio. In Figure 6, we plot Δ(D/T) of host galaxies measured between two snapshots on either side of the time of the most massive merger, defining the merger time as that when the satellite crosses a fixed distance of r merge = 20 kpc. The four panels show the mergers in different lookback time intervals, from the most recent (top left) to the earliest mergers (bottom right). We plot them in lookback time intervals since some galaxies had their most massive merger recently and some had them long ago and it is not immediately obvious that high-redshift galaxies should respond to mergers of a given mass ratio in the same way as low-redshift galaxies (e.g., because they have different sizes, gas mass fractions, etc.). However, inspection of the different panels suggests that, at least roughly, the mass threshold above which satellites are able to induce significant changes is about that of the stellar component of their hosts, M satM star, host, with no strong dependence on redshift. Note that higher frequency of data points in the bottom panels indicates that merger histories were more active before z ~ 1. As expected, disc galaxies (blue circles) are more sensitive to morphological changes than spheroids (red squares) and these changes are almost always towards dispersion-supported systems [i.e., Δ(D/T)<0]. This corresponds to a positive change in the Sérsic index, Δ(n)>0, as D/T is anti-correlated with n (Figure 2).

Figure 6. Changes in D/T in host galaxies measured just after and before the merging of the most massive satellite (taken when the satellite crosses at r merge = 20 kpc). The panels show mergers in different time intervals, from the most recent (top left) to the earliest (bottom right). Blue circles correspond to Δ(D/T) in disc galaxies and red squares to Δ(D/T) in spheroids. Significant D/T changes occur typically for satellites M satM star, host, and these changes are more pronounced for disc galaxies.

The large scatter in the Δ(D/T) data points suggests that changes in galaxy morphology depend on other factors as well, for example, on the amount of cold gas contained in these galaxies, orbital parameters, etc. In a few cases, galaxies can even show an increase in Δ(D/T) after mergers [see data points with Δ(D/T)>0]. This may suggest that some galaxies become more disc-like as a result of mergers, possibly fueled by the consistent amount of cold gas which accompanies these mergers; e.g., a bulge-dominated host galaxy could accrete a low-mass, gas-rich companion that brings in sufficient gas to build a disc. Most of the data points with Δ(D/T)>0 indeed correspond to galaxies which were spheroidal pre-merger. Note, however, that in their case, an increase in D/T does not necessarily translate into a lowering of the Sérsic index sufficiently close to 1, as can be inferred from the large range of possible D/T—n trajectories in Figure 2. The role of cold gas will be analysed in more detail in the following sections.

5 FACTORS THAT INFLUENCE THE PRESENT-DAY MORPHOLOGY

We have shown above that the majority of galaxies in the mass range under consideration undergo mergers that are expected to damage significantly (and possibly disrupt completely) pre-existing stellar discs. In spite of this, the majority of galaxies that are at present day in this mass range, both in nature and in these simulations, contain significant disc components. This suggests that discs can be re-established after mergers, via new star formation in gaseous discs (e.g., Robertson et al. Reference Robertson, Bullock, Cox, Di Matteo, Hernquist, Springel and Yoshida2006; Hopkins et al. Reference Hopkins, Cox, Younger and Hernquist2009). But not all the present-day simulated systems have significant discs—why not? And for those that do contain significant disc components, there is a large spread in ‘diskiness’ (e.g., D/T). What determines this spread? Clearly, relevant factors, besides the mass ratio of the merger, are going to be the time of the last massive merger (i.e., is there sufficient time between the merger and the present-day to reform a significant disc component?) and the amount of gas available post-merger to fuel the re-growth. We now examine the importance of these factors.

5.1. Dependence on merger mass ratio

In Figure 7, we plot the relation between the present-day morphology and the mass ratio of the last massive merger. By selection, we consider as massive mergers only those mergers with mass ratios exceeding unity, M sat/M star, host > 1, guided by Figure 6 which shows that such events typically induce a significant morphological change. Note that the mass ratio is defined in terms of the total mass of the satellite to the stellar mass of the host at the redshift of the merger (constrained to be z < 2).

Figure 7. Relation between the mass ratio of the last major merger and D/T at z = 0. Even though major mergers do have an immediate effect on the morphology of a galaxy (see Figure 6), there is virtually no correlation between the present-day morphology and the mass ratio of the last major merger since z = 2 (Spearman rank correlation coefficient r = −0.13).

It is evident from Figure 7 that there is no strong correlation between D/T at z = 0 and the mass ratio of the last massive merger. The Spearman rank correlation coefficient is weak, with r = −0.13. Note that this result is insensitive to our choice of definition of the mass ratio. For example, if we define the mass ratio in terms of the stellar mass of the host at z = 0 instead of at the redshift of the merger, we find a similarly poor correlation with the present-day morphology.

Taken together, Figures 6 and 7 therefore strongly suggest that the morphology is altered (again) following the last massive merger (i.e., through disc re-growth).

Note that some present-day disc galaxies may have had multiple massive mergers (i.e., with M sat/M star, host > 1) during their lifetime. Some of these mergers could have higher mass ratios than the last massive mergers. However, given the poor correlation between the present day morphologies and the properties of the last massive merger, it is unlikely that the conclusions of Figure 6 can change regarding correlations with the properties of earlier mergers (on the contrary, in that case we will expect an even weaker correlation).

What is the prevalence of the disc re-growth after mergers? In Figure 7, we looked only at the fate of galaxies that underwent massive (M sat, tot > M star, host) mergers—albeit, given the large redshift range under consideration, this comprises the majority of our galaxies. In Figure 8, we capture the morphological changes of all galaxies since a given time. As before, we divide galaxies in two categories, those that had a massive merger (M sat, tot > M star, host) and those that have not. The top panel shows the morphological changes of galaxies since z merge ⩽ 1 (or lookback time of ≃ 7 Gyr). With these criteria, 31% of all galaxies today are discs reformed after massive mergers. In contrast, only 19% of galaxies became (or remained) spheroids after a massive merger. A significant fraction, 43%, are present-day discs that had quiescent histories, i.e., no massive mergers since z = 1, while 7% are spheroids that also had no recent massive mergers. The bottom panel of Figure 8 shows that if we set the massive merger time scale further back to z = 2 (lookback time of ≃ 10 Gyr), the disc re-growth process is even more prevalent: 54% of all galaxies today are discs that had a massive merger. The rest, 22% are spheroids today which had a massive merger, 20% are discs that had no merger, and 4% are spheroids that had no merger. These plots show clearly the resilience of disc galaxies in face of disruptive mergers.

Figure 8. The distribution of galaxies, both with and without massive (M sat, tot > M star, host) mergers since z merge ⩽ 1 (top) and since z merge ⩽ 2 (bottom), respectively. The four categories are galaxies that are discs today and had a merger (blue), galaxies that are discs and did not undergo a merger (cyan), galaxies that are spheroids after a merger (orange), and spheroids that did not have a merger (red).

5.2. Dependence on cold gas fractions

As discussed in the Introduction, it has been proposed that the fraction of cold gas available at the time of mergers, can predict the (re)formation of disc galaxies after massive mergers. Here we revisit the relation between cold gas fractions and galaxy morphology (D/T) by tracking both self-consistently in a cosmological context. Note that here we define the cold gas mass fraction, f gas, as the ratio of gas mass to total massFootnote 2 within the central 20 kpc.

We examine the relation between present-day ‘diskiness’ and gas fractions on a per-galaxy basis. Figure 9 shows the correlation between the morphologies of present-day galaxies and the fraction of gas f gas present within the central 20 kpc of the host at the time of the most massive merger for major merger cases (i.e., mass of the satellite exceeded M star, host at collision). We experiment with using the gas fraction defined both immediately pre- and post-merger. In both cases, there are significant correlations with present-day morphology. The correlation is particularly strong (with a Spearman rank correlation coefficient of 0.66) when using the gas mass fraction measured immediately post-merger.

Figure 9. The correlation between galaxy morphologies (D/T) at z = 0 and f gas(< 20 kpc) at the time of the most massive >M star, host merger. The gas fractions after the merger (filled blue circles) exhibit a stronger correlation with D/T (z = 0) than the fractions computed prior to the merger (filled red squares). The Spearman rank coefficient for the post-merger f gas − D/T (z = 0) correlation is 0.66, while that of the pre-merger f gas − D/T (z = 0) correlation is 0.31.

We note that using the same GIMIC simulations, Sales et al. (Reference Sales, Navarro, Theuns, Schaye, White, Frenk, Crain and Dalla Vecchia2012) found that galaxy morphologies at z = 0 depend on the fraction of the hot gas in the host galaxy rather than that of the cold gas. However, this is likely the result of the inclusion of much more massive galaxies in their sample (M 200 ≃ 1–3 × 1012M). More massive galaxies naturally have higher f hot, but in GIMIC, because they are likely to be over-cooled, they can also have artificially compact/robust discs with high D/T ratios.

Where does the gas that fuels disc (re)growth come from? Most of the gas participating in star formation has been accreted smoothly, rather than being brought in by satellites. For example, in a sub-set of the OWLS simulations similar to GIMIC Footnote 3 , van de Voort et al. (Reference van de Voort, Schaye, Booth, Haas and Dalla Vecchia2011) find that the gas associated with substructure comprises only ~10% to the total gas budget in ~1012M mass galaxies (see their Figure 3). This is likely the result of the strong stellar feedback implemented in both of these simulations which unbinds a large fraction of gas from lower mass dark matter subhaloes. Other studies obtain similar results. In particular, Brooks et al. (Reference Brooks, Governato, Quinn, Brook and Wadsley2009) find that in sub-L * galaxies, cold flow gas accretion is responsible for star formation in the disc throughout the galaxy’s lifetime. These results suggest a direct relation between the fraction of cold gas and disc morphologies.

Understanding the mechanisms by which cold gas operates on the disc structure is also important. In principle, there are two distinct channels: one in which its acts mainly towards (re)forming the stellar discs after the mergers (which is what we have mainly focused on so far), and the other in which the cold gas mitigates the tidal impact and increases the resilience of discs to mergers. An example of direct mitigation is provided by Moster et al. (Reference Moster, Macciò, Somerville, Johansson and Naab2010) who show that the cold gas in the disc can absorb part of the tidal energy of the merger into its thermal energy (and radiate it later) and consequently, the stellar disc maintains a post-merger scale-height consistent with the observations. However, this mechanism is unlikely to be efficient in the case of massive mergers (indeed, we have already shown that 1:1 satellite-to-galaxy stellar mass mergers usually induce very large changes to the kinematic properties of the central galaxy), and possibly also in the case of many minor mergers following in short succession.

Another suggestion is that the prevalence of present-day discs is achieved via efficient feedback which efficiently removes gas from systems until after the main merger activity has subsided (z ~ 1), the gas is then re-accreted and forms a disc (Weil, Eke, & Efstathiou Reference Weil, Eke and Efstathiou1998). While efficient feedback to prevent excessive star formation at high redshift is certainly important, it cannot by itself be the whole story. For example, it cannot easily explain the observations of large numbers of disc galaxies out to z ~ 2 (see van der Kruit & Freeman Reference van der Kruit and Freeman2011 and references therein) or the fact that a fraction of the Milky Way thin disc has formed before z ~ 1 (Wyse Reference Wyse, Funes and Corsini2001; Haywood et al. Reference Haywood, Di Matteo, Lehnert, Katz and Gómez2013).

If mitigating mechanisms are indeed generally inefficient, the explanation for the present-day abundance of disc galaxies must rely on the efficient star-formation activity which promotes the re-growth of stellar discs (Hammer et al. Reference Hammer, Puech, Chemin, Flores and Lehnert2007; Puech et al. Reference Puech, Hammer, Hopkins, Athanassoula, Flores, Rodrigues, Wang and Yang2012). This process, which entails successive morphological transformations during the lifetime of a galaxy, lies at the basis of forming large discs in GIMIC and it will be investigated in more detail in Section 5.4.

5.3. Dependence on time since the last massive merger

Another key factor which can influence the (re)formation of discs is the amount of time elapsed between the last massive merger and the time of observation (the present day in this case). Figure 10 shows the distribution of the time of the last massive mergers (>M star, host) for present-day galaxies categorised broadly into disc and spheroid galaxies. Most disc galaxies have had their last massive merger prior to z ~ 1 (≃ 7–8 Gyr ago). Galaxies with recent mergers tend to become spheroids, especially if f gas at the time of merger is low (which is likely at z < 1). Note that this figure does not differentiate between the mass ratios of different mergers. Of course, galaxies which experience mergers of higher mass ratio are more likely to become spheroids (see Figure 6 and Section 5.4). These results suggest that there are important differences in the merger histories of disc and spheroid galaxies of fixed (stellar) mass.

Figure 10. The distribution of the times since the last massive (M sat/M star, tot > 1 : 1) merger for disc (D/T ⩾0.3; blue curve) and spheroid (D/T ⩽0.3; red curve) galaxies at z = 0. The error bars represent Poisson uncertainties. M sat is measured when the satellites first cross r merge = 20 kpc (see text). Present-day disc galaxies have had more quiescent recent histories compared to spheroids of the same stellar mass.

Consistent with Figure 7, Figure 10 also indicates that quiescent merger histories are not a prerequisite for the formation of large disc galaxies. Recall that all disc galaxies in this plot have non-quiescent merger histories, i.e., mergers >M star, host. Second, a non-negligible fraction of these have had their last >M star, host since z ~ 1. The likelihood of disc galaxies forming via more quiescent merger histories than shown in Figure 10, e.g., with no mergers as massive as M star, host since z = 2 is low, <20% (see the dashed orange line in Figure 5). Therefore, the formation of the Milky Way via a very quiescent merger history cannot be ruled out in a ΛCDM model, even though it is statistically unlikelyFootnote 4 (the likelihood is even lower, <10%, if we require that Milky Way experiences only mergers ⩽0.5M star, host, i.e., ⩽Mstar, disc since z = 2; see the red dashed line in Figure 5). On the other hand, quiescent merger histories, by themselves, do not guarantee the emergence of galaxy discs. The misalignment of angular momenta of the infalling gas may transform a disc galaxy into a spheroid even in the absence of mergers (Sales et al. Reference Sales, Navarro, Theuns, Schaye, White, Frenk, Crain and Dalla Vecchia2012).

5.4. Cold gas fractions and merger time combined: The diversity of pathways for forming disc galaxies

So far we have studied the role of cold gas fractions and merger histories separately and have found both to be important. In reality, these two factors are inter-related. Figure 11 encapsulates the various likelihoods of forming disc (D/T > 0.3) and spheroidal (D/T < 0.3) galaxies, as a function of the mass ratio of their last massive (> M star, host) mergers (the three rows) and as a function of the average f gas(< 20 kpc) (dashed black lines in each panel). As before, we focus only on galaxies with non-quiescent merger histories, which are typical in a hierarchical cosmology. The mass thresholds for these mergers are, from top row to bottom row, > M star, host, > 3M star, host, and > 10M star, host. The coloured lines in each panel show the D/T histories of individual galaxies, with the time being measured with respect to the time of the last massive merger for that galaxy, where only mergers with mass ratios above the threshold corresponding to each row are considered. (Note that, in this tally, some mergers can be captured in more than one panel, e.g., a merger with > 3M star, host may appear in a panel with > M star, host, if that was the last massive merger experienced by the galaxy).

Figure 11. Various D/T trajectories (pathways) for forming disc galaxies and spheroids including all possible morphological transformations (the four columns): spheroid today–spheroid pre-merger, spheroid today–disc pre-merger, disc today–spheroid pre-merger, and disc today–disc pre-merger. The percentage at the bottom left of each panel indicates the fraction of galaxies in the original sample which undergo these transformations. The three rows from top to bottom show galaxies with last massive mergers above the thresholds: > M star, host, > 3M star, host and > 10M star, host. The coloured lines in each panel show the D/T trajectories of individual galaxies and the dashed black lines in each panel indicate the median f gas/f b within 20 kpc. t = 0 represents the time of the last massive merger, with the mass ratio threshold indicated on the right vertical axis. Approximately half of all galaxies today (in this mass range) are both disc-dominated and have had a massive merger at some point in their past. Approximately half of these galaxies were discs prior to the major merger and re-grew their disc afterwards (while the other half were spheroids prior the last massive merger and grew discs later on).

The four columns from left to right tally all possible morphological transformations between the time just prior to the last massive merger and z = 0: spheroid–spheroid, disc–spheroid, spheroid–disc, and disc–disc. The percentage at the bottom left of each panel represents the fraction of galaxies relative to the total number of systems in the original sample which undergo these transformations (note that the total number also includes galaxies with quiescent histories or those with non-massive mergers). For example, the two rightmost panels on the top row show that about 50% of all galaxies experience a merger > M star, host since z = 2 and yet are disc-like today. About 23% of sample galaxies were spheroids before the last > M star, host merger and are disc-like today, while a similar fraction (~28%) were disc-like before their last > M star, host merger and are still disc-like today (however, these are usually not the same discs). The formation of discs after the mergers is more likely to occur when the fraction of cold gas is high, f gas/f b > 0.4 (where f b = Ω b m), irrespective of whether galaxies were spheroids or discs before the merger.

Disc galaxies sometimes manage to form even in the case of very massive mergers, albeit the likelihood of this happening is very low. For example, about 50% of sampled galaxies have mergers M sat > 3M star, host and most of them become disc galaxies by z = 0. About 30% of all galaxies in our mass range may form discs this way (the two rightmost panels in middle row). Interestingly, disc galaxies can form even after mergers >10M star, host (about 16.8% of all sample galaxies). Again, the determining factor is the high gas fraction (f gas > 0.4) at the time of merger and thereafter.

In summary, quiescent merger histories are certainly not a prerequisite for the formation of disc galaxies. Most galaxies undergo mergers massive enough to significantly affect/destroy stellar discs (M satM star, host), however new discs can often form afterwards, even when these mergers are relatively recent (e.g., z ~ 1, recall Figure 10). These results run counter to the expectations from collisionless studies in which mergers of this massive will permanently turn discs into spheroids.

We note that the diversity of merger histories of disc galaxies has been noted before by Martig et al. (Reference Martig, Bournaud, Croton, Dekel and Teyssier2012), who found little correlation between the morphologies of disc galaxies today and of their progenitors at z ~ 1. These authors also note that the thinnest disc galaxies in their sample are formed in quiescent histories and suggest a quiescent formation scenario for the Milky Way.

6 THE DISC RE-GROWTH SCENARIO IN THE CONTEXT OF OBSERVATIONS

As we have argued so far, disc galaxies can form in the context of violent mergers. This does not preclude the disruption of discs by the incoming mergers (quite the contrary, we have shown clear morphological changes result from these mergers). So a process of disc re-growth has to happen, facilitated by the abundance of cold gas around these galaxies. Here we examine some of the observational evidence that may support this scenario.

6.1. The mass growth of discs and the discs stellar ages

First, there is evidence that stellar discs grow significantly in mass at recent times. Studies that examined the stellar mass growth of typical disc galaxies (by looking at their likely progenitors) have found that they typically double their stellar mass since z ~ 1 (Bell et al. Reference Bell2005; Hammer et al. Reference Hammer, Flores, Elbaz, Zheng, Liang and Cesarsky2005; Patel et al. Reference Patel2013; van Dokkum et al. Reference van Dokkum2013; Papovich et al. Reference Papovich2015). Thus, there is clearly significant (re)growth post the main merger period, in support of the general ideas advocated above. In Figure 12, we make a more quantitative comparison—the stellar mass growth of the simulated disc galaxies with that recently inferred for Milky Way- and M31-like progenitors from ZFOURGE/CANDELS data by Papovich et al. (Reference Papovich2015). These authors traced the evolution of systems with present-day stellar masses of 5 × 1010M (MW-like) and 1011M (M31-like) back in redshift, effectively identifying analogues of their progenitors in the ZFOURGE/CANDELS survey as systems with the same comoving number density as the z = 0 systems. Overall the growth of stellar massFootnote 5 in the simulated galaxies is reasonably compatible with the observations. Furthermore, we note that the growth of the mass of the stellar discs in the simulations tracks the total stellar mass growth closely below z ~ 1, indicating that this is the dominant period of disc formation in the simulations.

Figure 12. The growth in stellar mass in the simulated disc galaxies, compared to that inferred for Milky Way- and M31-like progenitors from the ZFOURGE/CANDELS survey (Papovich et al. Reference Papovich2015). Both the simulated and observed galaxies effectively double their stellar mass content since z ~ 1 (i.e., post the main merger period). The growth of stellar discs (dashed green curve) tracks the total stellar mass growth since z ~ 1 in the simulations.

The median age of the disc stars can be another indication. Since the merger activity of most disc galaxies continues until z ~ 1, a typical stellar disc that re-forms post-merger will contain a significant fraction of young and/or intermediate age stars. The median ages of our simulated discs are about 5–6 Gyr. This compares well with the inferred half-age of the Milky Way disc, of ~6.9 Gyr (Aumer & Binney Reference Aumer and Binney2009). The luminosity-weighted disc ages are, as expected, younger for systems with ongoing star formation. Figure 13 shows a comparison between the r-band luminosity-weighted ages in our simulated discs and the data of Gallazzi et al. (Reference Gallazzi, Charlot, Brinchmann, White and Tremonti2005). Similar younger ages are also obtained in a local sample of disc galaxies by Yoachim & Dalcanton (Reference Yoachim and Dalcanton2008).

Figure 13. The the (r-band) luminosity-weighted ages of the simulated discs (black circles) compared with the data of Gallazzi et al. (Reference Gallazzi, Charlot, Brinchmann, White and Tremonti2005) (shaded region). As typical disc galaxies exhibit merger activity until z ~ 1, the stellar discs are generally young/intermediate-age, although recent/ongoing star formation biases the luminosity-weighted ages towards lower values (see text).

Of course, not all disc galaxies in the observational sample may have underwent massive mergers. However, the simulated sample shown in this plot includes also all disc galaxies, some of which also did not undergo massive mergers. The premise of this comparison is that within the context of the ΛCDM model, the majority of disc galaxies observed at z = 0 experience such mergers, as shown by our simulations.

7 CONCLUSIONS

Reconciling the ubiquity of disc galaxies at the present day with the prevalence of (apparently) disc-destroying mergers that galaxies face in the ΛCDM cosmological context has been a subject of intense research for several decades. While progress was undoubtedly stalled due to issues linked to overcooling/inefficient feedback (leading to overly spheroidal galaxies) in earlier simulations, the current generation of cosmological hydrodynamical simulations can now, generally speaking, successfully produce large populations of disc galaxies whose properties compare favourably to observations (e.g., Vogelsberger et al. Reference Vogelsberger2014; Hopkins et al. Reference Hopkins, Kereš, Oñorbe, Faucher-Giguère, Quataert, Murray and Bullock2014; Schaye et al. Reference Schaye2015). The implication of this development is that the ΛCDM cosmological model is a perfectly viable setting for the emergence of a large disc galaxy populations. The aim of the present study is to help elucidate the physics that enables galaxies to retain (or re-form) their discs, and to clarify the somewhat unclear picture that has emerged from studies based on previous zoomed simulations of small numbers of systems.

The main results our study can be summarised as follows:

  • A quiescent merger history is not a prerequisite for the existence of disc galaxies today. We find that more than half of simulated galaxies had at least one merger with a mass ⩾ M star, host sometime since z = 2 and yet are disc galaxies today, while a third and one-sixth of galaxies experienced mergers ⩾ 3M star, host and ⩾ 10M star, host, respectively, and still they have disc morphologies today (see Figure 11). One half of the M sat > M star, host impacts occur at look-back time of ⩽6–7 Gyr. The pathways by which disc galaxies can emerge from merger-induced morphological transformations are remarkably diverse. Most galaxies undergo relatively frequent morphological transformations by the present day.

  • The majority (approximately 80%) of galaxies in the mass range under consideration undergo massive mergers (with M satM star, host) since z = 2. Such mergers typically induce large changes in the morphology of disc-dominated galaxies. In spite of this, there is essentially no correlation between the present-day morphology of galaxies and the mass ratio of the last massive merger, indicating that the morphology is altered again (i.e., the disc re-grows) post-merger. Disc re-growth occurs in more than half of all galaxies over the past ~10 Gyr and for about a third of galaxies over the past ~7 Gyr.

  • Galaxies with high gas fractions either immediately pre- or (especially) post-merger can reform their discs, particularly if the last massive merger occurred at z ~ 1 or earlier.

The results presented here apply to ‘normal’ systems with present-day masses of ~1010M, which is roughly the mass scale that has the largest fraction of systems with significant disc components in the local Universe and where the GIMIC simulations reproduce the observable properties of galaxies relatively well. These simulations lack the resolution to explore the morphologies of galaxy’s significantly below this mass scale, and they lack high-efficiency feedback (i.e., from AGN) required to prevent overcooling in significantly more massive systems. Note, however, for dwarf galaxies, it is already known that quiescent formation is not necessary to obtain stellar discs (see, for example, Brook et al. Reference Brook2011). It is clearly of interest to perform the kind of analysis done above the Milky Way mass scale, in an attempt to understand why disc formation is so inefficient on those scales. The advent of a new generation of simulations, such as Illustris, EAGLE, and Horizon-AGN (which extend to larger volumes and include AGN feedback), represent promising tools for pursuing this line of research for more massive systems, while much higher-resolution ‘zoom’ simulations (e.g., FIRE, APOSTLE) are best suited to investigate the morphologies of lower mass systems.

ACKNOWLEDGEMENTS

The authors thank the referee, Fabio Governato, for his constructive comments and suggestions that helped improved the paper. They also thank Peter Yoachim for providing the observational data in Figure 1 in electronic format, Peter Behroozi for helpful comments, and the EAGLE team for providing a comparison sample from their simulations. During part of this project, ASF was supported by a Royal Society Dorothy Hodgkin Fellowship. IGM is supported by a STFC Advanced Fellowship. RAC is a Royal Society University Research Fellow. AMCLB acknowledges support from an internally funded PhD studentship at the Astrophysics Research Institute of Liverpool John Moores University. The authors thank their collaborators within the Virgo Consortium for support with the development of the original GIMIC simulations. The two high resolution runs discussed here were performed on the Darwin Supercomputer at the University of Cambridge.

A COMPARISON TO EAGLE

Here we compare the z = 0 stellar mass−halo mass relations, stellar mass−size relations, and the morphologies of the GIMIC galaxies with those derived from the recent EAGLE simulations (Schaye et al. Reference Schaye2015). For the EAGLE simulations, we use the fiducial reference (REF) model at the fiducial resolution (which is similar to the high-res. GIMIC runs that we use here) and the recalibrated (RECAL) model for the higher resolution EAGLE runs (which are a factor of 8/2 better mass/spatial resolution compared to the fiducial resolution runs, respectively). We select EAGLE galaxies in the same stellar mass range used for our GIMIC analysis from the 25 Mpc h−1 runs, resulting in 43 EAGLE galaxies for the REF-L0025N0376 run and 56 EAGLE galaxies for the RECAL-L0025N752 run, respectively.

In Figure 14, we compare the present-day stellar mass−halo mass relations (left panel) and stellar mass−half-mass radius relations (right panel) of GIMIC with the recent EAGLE simulations. At stellar masses of less than approximately 1010 M, the simulations predict similar stellar mass−halo mass relations. Over this range of masses, the GIMIC galaxies have slightly larger half-mass radii but there is significant overlap with the EAGLE galaxies. At higher stellar masses, the GIMIC simulations suffer from overcooling, resulting in higher stellar masses for a given halo mass and galaxies that are too compact (see also McCarthy et al. Reference McCarthy, Schaye, Font, Theuns, Frenk, Crain and Dalla Vecchia2012b).

Figure 14. Comparison of the present-day stellar mass−halo mass relations (left) and stellar mass−half-mass radius relations (right) of GIMIC with the recent EAGLE simulations. The half-mass radius, r star, 1/2, is defined as the radius which encloses half of the total stellar mass bound to the galaxy’s halo (excluding the stellar mass of any satellites). At stellar masses of less than approximately 1010 M, the simulations predict similar stellar mass−halo mass relations, while the GIMIC galaxies have slightly larger half-mass radii. At higher stellar masses, the GIMIC simulations suffer from overcooling, resulting in higher stellar masses for a given halo mass and galaxies that are too compact (see also McCarthy et al. Reference McCarthy, Schaye, Font, Theuns, Frenk, Crain and Dalla Vecchia2012b).

We compare the D/T probability distribution functions of GIMIC and the two EAGLE models in Figure 15, where we have computed D/T in a consistent way for all of the simulations using the method described in the main text. As can be seen, the three simulations have similar D/T distributions.

Figure 15. Comparison of the present-day D/T distribution of GIMIC with the recent EAGLE simulations. The D/T distributions are very similar.

B SYNTHETIC GAMA IMAGES

To make a like-with-like comparison to the observational data, we produce synthetic GAMA r-band images of the simulated galaxies in both face-on and edge-on configurations. Specifically, for each star particle in a simulated galaxy, we estimate the (unabsorbed) r-band luminosity by treating it as a simple stellar population. In particular, we use its initial stellar mass, metallicity, and age (and assume a Chabrier IMF) to interpolate a spectrum using the GALAXEV population synthesis package of Bruzual & Charlot (Reference Bruzual and Charlot2003). We then apply the SDSS r-band transmission filter to the spectrum and then integrate it to obtain the r-band luminosity of the particle. We place each simulated galaxy at a redshift of z = 0.1 and we project the luminosities of all of the particles to produce two maps for each simulated galaxy (edge-on and face-on configurations), using a triangular-shaped-clouds interpolation scheme. Each pixel has an angular size of 0.339 arcsec, corresponding to that adopted in the GAMA analysis, and each image has 101 pixels on a side, which spans a physical length of ≈63 kpc at the adopted redshift (assuming H 0 = 70 km s−1 Mpc−1).

At this stage, we have flux images in units of ergs s−1 cm−2. We convert the flux images into counts images by multiplying by the SDSS exposure time of 53.9 s and the physical area of the telescope. We further assume that the photons all have the same energy (corresponding to the effective wavelength of the r-band filter, 0.6231 microns) and that the gain (converting photons to electrons) is unity. We then add a realistic sky component to the images (corresponding to 20.8 mag arcsec−2). Finally, we Poisson sample the galaxy + sky counts images and then subtract the sky (as done in GAMA data analysis).

The synthetic maps are convolved with the SDSS r-band point spread function (treated here as a Gaussian with a FWHM = 1.1 arcsec) and then processed through the same Sérsic model fitting software applied to the real GAMA observational data [which uses the GALFIT software package of Peng et al. (Reference Peng, Ho, Impey and Rix2002), to do the actual fitting], providing us with estimates of the Sérsic indices of each of the simulated galaxies. The Sérsic model fitting yields estimates of the effective radius, the Sérsic index, the axial ratio, the position angle, the total magnitude, and the centre coordinates.

Here we provide an example from our synthetic GAMA imaging and surface brightness modelling pipeline. Shown in Figure 16, are virtual r-band counts images of a typical simulated galaxy, placed at z = 0.1. The images show the galaxy both in edge-on and face-on configurations and with and without Poisson sampling noise (see caption). This particular galaxy has a strongly disky appearance with a hint of spiral structure when viewed in a face-on configuration. The galaxy is sufficiently bright that the main surface brightness features are still clearly visible even when noise is added, although note that these images have not been convolved with the telescope point spread function.

Figure 16. Synthetic r-band counts images of a typical simulated galaxy, placed at z = 0.1. Each image has 1012 pixels of length 0.339 arcsec, spanning a field of view of approximately 63 kpc. The images are shown on a logarithmic scale, spanning a dynamic range of 4 orders of magnitude (i.e., white corresponds to the maximum and deep red corresponds to a counts level that is 4 orders of magnitude lower; black corresponds to an absence of counts). The images in the top row show a show the galaxy in edge-on configuration, while the bottom row shows the galaxy in a face-on configuration. The left-hand column shows the raw simulation images, while the right-hand column shows the images after (i) a sky component was added; (ii) the images were Poisson sampled; and (iii) the sky was re-subtracted. Note that the images have been convolved with the SDSS point spread function here.

In Figure 17, we show the best-fit 2D Sérsic model to the same simulated galaxy. Overall, a single Sérsic profile with an index of approximately 1 (i.e., an exponential distribution) describes the surface brightness distribution of this simulated galaxy rather well, even if the model cannot reproduce the detailed spiral structure of the galaxy (nor would it do so for real galaxies with prominent spiral structure).

Figure 17. Surface brightness modelling of the simulated galaxy shown in Figure 16. The top row shows the noisy, PSF-convolved image of the galaxy in a face-on configuration (top left), the best-fit PSF-convolved 2D ellipsoidal Sérsic model (top middle), and the difference between the two previous images (top right). The bottom row shows the best-fit Sérsic index and half-light radius of this galaxy (green circle) compared to the overall simulated population (bottom left) and the surface brightness profile of the galaxy along with the best-fit Sérsic model (bottom right).

Footnotes

2 We have also tried defining the gas mass fraction just in terms of the baryonic component (i.e., f gas = M gas/M (gas + stars)), as in some previous studies (e.g., Hopkins et al. Reference Hopkins, Cox, Younger and Hernquist2009), and find qualitatively similar results.

3 Their model REF-L050N512 uses the same prescriptions for feedback (Dalla Vecchia & Schaye Reference Dalla Vecchia and Schaye2008) and the same code. The mass-loading factor is a factor of two higher in GIMIC; however, this does not change the star formation histories of galaxies significantly (see Sales et al. Reference Sales, Navarro, Schaye, Dalla Vecchia, Springel and Booth2010).

4 It is interesting to note here that a future merger with the Large Magellanic Cloud will not be far from a 1:1 case when comparing the total mass of the LMC to the Milky Way’s stellar mass.

5 Note that this is the instantaneous stellar mass at a given redshift z; i.e., it is not equivalent to the integral of the star formation history from high redshift down to z, as some stellar mass is lost over time due to stellar evolution (both in the simulations and in nature).

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Figure 1. Comparison of the distribution of Sérsic indices from GIMIC (thick solid black curve) with that derived from the analysis of local (0.07 < z < 0.12) GAMA galaxies, selected to be in the same stellar mass range applied to the simulated galaxies (thick solid red curve; Kelvin et al. 2012). The error bars correspond to the Poisson errors, derived by taking the square root of the number of galaxies in each Sérsic index bin. To derive the Sérsic indices of the simulated galaxies, we create synthetic GAMA-like images of the simulated galaxies, accounting for the effects of the SDSS telescope point spread function and Poisson noise (due to both the galaxy and the sky; see Appendix B for further details). The thin short-dashed, long-dashed, and dot-dashed black curves show the effects of switching on/off the modelling of Poisson noise and the point spread function. The simulated galaxy population has a qualitatively similar distribution of morphologies to that of the observed GAMA sample.

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Figure 2. The z = 0 relation between the kinematic D/T and the apparent (2D) morphology, as characterised by the Sérsic index derived from synthetic images of GIMIC galaxies. Although significant scatter is present, a strong anti-correlation is clearly visible, such that high values of D/T correspond to low values of the Sérsic index. The vertical dotted line at D/T = 0.3 corresponds to our fiducial dividing line between disc-dominated and bulge-dominated systems, which also roughly delineates the systems into high and low values of the Sérsic index.

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Figure 3. Comparison of disc scale-heights (Left) and scale-lengths (Right) of simulated galaxies in GIMIC (black circles) with those measured for nearby galaxies by Kregel et al. (2002) and Yoachim & Dalcanton (2006) (red and blue diamonds) versus the maximum rotation speeds Vrot. The dashed horizontal line shows the (Plummer equivalent) force softening of the simulations. Over the range of masses considered here, the simulated galaxies have broadly realistic sizes.

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Figure 4. The cumulative fraction of haloes (median M200 = 1011.7 M) which have mergers with mass ratios XMsat, max/M200(z = 0) > 0.01 (red), >0.03 (orange), >0.10 (green), and >0.15 (blue).

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Figure 5. The cumulative fraction of galaxies that have mergers with mass ratios: XMsat/Mstar, host > 10 (blue), >3 (green), 1.0 (orange), and >0.5 (red). Solid lines correspond to the case when the satellite crossed r200(z) and dashed lines when the satellite crossed a fixed physical radius of 20 kpc.

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Figure 6. Changes in D/T in host galaxies measured just after and before the merging of the most massive satellite (taken when the satellite crosses at rmerge = 20 kpc). The panels show mergers in different time intervals, from the most recent (top left) to the earliest (bottom right). Blue circles correspond to Δ(D/T) in disc galaxies and red squares to Δ(D/T) in spheroids. Significant D/T changes occur typically for satellites MsatMstar, host, and these changes are more pronounced for disc galaxies.

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Figure 7. Relation between the mass ratio of the last major merger and D/T at z = 0. Even though major mergers do have an immediate effect on the morphology of a galaxy (see Figure 6), there is virtually no correlation between the present-day morphology and the mass ratio of the last major merger since z = 2 (Spearman rank correlation coefficient r = −0.13).

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Figure 8. The distribution of galaxies, both with and without massive (Msat, tot > Mstar, host) mergers since zmerge ⩽ 1 (top) and since zmerge ⩽ 2 (bottom), respectively. The four categories are galaxies that are discs today and had a merger (blue), galaxies that are discs and did not undergo a merger (cyan), galaxies that are spheroids after a merger (orange), and spheroids that did not have a merger (red).

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Figure 9. The correlation between galaxy morphologies (D/T) at z = 0 and fgas(< 20 kpc) at the time of the most massive >Mstar, host merger. The gas fractions after the merger (filled blue circles) exhibit a stronger correlation with D/T (z = 0) than the fractions computed prior to the merger (filled red squares). The Spearman rank coefficient for the post-merger fgas − D/T (z = 0) correlation is 0.66, while that of the pre-merger fgas − D/T (z = 0) correlation is 0.31.

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Figure 10. The distribution of the times since the last massive (Msat/Mstar, tot > 1 : 1) merger for disc (D/T ⩾0.3; blue curve) and spheroid (D/T ⩽0.3; red curve) galaxies at z = 0. The error bars represent Poisson uncertainties. Msat is measured when the satellites first cross rmerge = 20 kpc (see text). Present-day disc galaxies have had more quiescent recent histories compared to spheroids of the same stellar mass.

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Figure 11. Various D/T trajectories (pathways) for forming disc galaxies and spheroids including all possible morphological transformations (the four columns): spheroid today–spheroid pre-merger, spheroid today–disc pre-merger, disc today–spheroid pre-merger, and disc today–disc pre-merger. The percentage at the bottom left of each panel indicates the fraction of galaxies in the original sample which undergo these transformations. The three rows from top to bottom show galaxies with last massive mergers above the thresholds: > Mstar, host, > 3Mstar, host and > 10Mstar, host. The coloured lines in each panel show the D/T trajectories of individual galaxies and the dashed black lines in each panel indicate the median fgas/fb within 20 kpc. t = 0 represents the time of the last massive merger, with the mass ratio threshold indicated on the right vertical axis. Approximately half of all galaxies today (in this mass range) are both disc-dominated and have had a massive merger at some point in their past. Approximately half of these galaxies were discs prior to the major merger and re-grew their disc afterwards (while the other half were spheroids prior the last massive merger and grew discs later on).

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Figure 12. The growth in stellar mass in the simulated disc galaxies, compared to that inferred for Milky Way- and M31-like progenitors from the ZFOURGE/CANDELS survey (Papovich et al. 2015). Both the simulated and observed galaxies effectively double their stellar mass content since z ~ 1 (i.e., post the main merger period). The growth of stellar discs (dashed green curve) tracks the total stellar mass growth since z ~ 1 in the simulations.

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Figure 13. The the (r-band) luminosity-weighted ages of the simulated discs (black circles) compared with the data of Gallazzi et al. (2005) (shaded region). As typical disc galaxies exhibit merger activity until z ~ 1, the stellar discs are generally young/intermediate-age, although recent/ongoing star formation biases the luminosity-weighted ages towards lower values (see text).

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Figure 14. Comparison of the present-day stellar mass−halo mass relations (left) and stellar mass−half-mass radius relations (right) of GIMIC with the recent EAGLE simulations. The half-mass radius, rstar, 1/2, is defined as the radius which encloses half of the total stellar mass bound to the galaxy’s halo (excluding the stellar mass of any satellites). At stellar masses of less than approximately 1010 M, the simulations predict similar stellar mass−halo mass relations, while the GIMIC galaxies have slightly larger half-mass radii. At higher stellar masses, the GIMIC simulations suffer from overcooling, resulting in higher stellar masses for a given halo mass and galaxies that are too compact (see also McCarthy et al. 2012b).

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Figure 15. Comparison of the present-day D/T distribution of GIMIC with the recent EAGLE simulations. The D/T distributions are very similar.

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Figure 16. Synthetic r-band counts images of a typical simulated galaxy, placed at z = 0.1. Each image has 1012 pixels of length 0.339 arcsec, spanning a field of view of approximately 63 kpc. The images are shown on a logarithmic scale, spanning a dynamic range of 4 orders of magnitude (i.e., white corresponds to the maximum and deep red corresponds to a counts level that is 4 orders of magnitude lower; black corresponds to an absence of counts). The images in the top row show a show the galaxy in edge-on configuration, while the bottom row shows the galaxy in a face-on configuration. The left-hand column shows the raw simulation images, while the right-hand column shows the images after (i) a sky component was added; (ii) the images were Poisson sampled; and (iii) the sky was re-subtracted. Note that the images have been convolved with the SDSS point spread function here.

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Figure 17. Surface brightness modelling of the simulated galaxy shown in Figure 16. The top row shows the noisy, PSF-convolved image of the galaxy in a face-on configuration (top left), the best-fit PSF-convolved 2D ellipsoidal Sérsic model (top middle), and the difference between the two previous images (top right). The bottom row shows the best-fit Sérsic index and half-light radius of this galaxy (green circle) compared to the overall simulated population (bottom left) and the surface brightness profile of the galaxy along with the best-fit Sérsic model (bottom right).