A physically motivated definition for the size of galaxies in an era of ultradeep imaging

Trujillo, Ignacio; Chamba, Nushkia; Knapen, Johan H.

doi:10.1093/mnras/staa236

Cited by 77 publications

(105 citation statements)

References 94 publications

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“…Similar to the break in the r-band profiles in Fig. 6, the up-turn in colours is plausibly the result of a transition from a disc-dominated region (e.g., Trujillo et al 2020) to the in situ-dominated stellar halo. The up-turn happens at slightly larger radii in the simulations, which may be due to the simulations having somewhat flatter metallicity gradients compared to the observations (see Fig.…”

Section: Colour and Age Profilessupporting

confidence: 63%

“…This figure shows, again, very good agreement with the observations. The observed light profiles display breaks around 10-20 kpc, which plausibly demarcates the transition from the disc to the stellar halo component (e.g., Trujillo et al 2020; note that the curves are total surface brightness profiles, not just the bulge+halo component). We also show the stacked SDSS DR9 r-band profile of D'Souza et al (2014) for Milky Way-mass galaxies (selected purely on stellar mass with no morphological criterion, as in the case of ARTEMIS), which is in excellent agreement with the simulations.…”

Section: Surface Brightness Profilesmentioning

confidence: 82%

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The artemis simulations: stellar haloes of Milky Way-mass galaxies

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McCarthy

Poole-McKenzie

et al. 2020

Monthly Notices of the Royal Astronomical Society

112

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We introduce the ARTEMIS simulations, a new set of 42 zoomed-in, high-resolution (baryon particle mass of ≈2 × 104 M⊙/h), hydrodynamical simulations of galaxies residing in haloes of Milky Way mass, simulated with the EAGLE galaxy formation code with re-calibrated stellar feedback. In this study, we analyse the structure of stellar haloes, specifically the mass density, surface brightness, metallicity, colour and age radial profiles, finding generally very good agreement with recent observations of local galaxies. The stellar density profiles are well fitted by broken power laws, with inner slopes of ≈−3, outer slopes of ≈−4 and break radii that are typically ≈20–40 kpc. The break radii generally mark the transition between in situ formation and accretion-driven formation of the halo. The metallicity, colour and age profiles show mild large-scale gradients, particularly when spherically-averaged or viewed along the major axes. Along the minor axes, however, the profiles are nearly flat, in agreement with observations. Overall, the structural properties can be understood by two factors: that in situ stars dominate the inner regions and that they reside in a spatially-flattened distribution that is aligned with the disc. Observations targeting both the major and minor axes of galaxies are thus required to obtain a complete picture of stellar haloes.

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Section: Colour and Age Profilessupporting

confidence: 63%

Section: Surface Brightness Profilesmentioning

confidence: 82%

The artemis simulations: stellar haloes of Milky Way-mass galaxies

Font

McCarthy

Poole-McKenzie

et al. 2020

Monthly Notices of the Royal Astronomical Society

112

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“…Recently, the mass-size relation for galaxies generally has come under additional scrutiny due to the recent rediscovery of sometimes abundant populations of extremely extended but low-mass galaxies in clusters, originally identified by Binggeli et al (1985) in the Virgo Cluster, now broadly referred to as ultra-diffuse galaxies (e.g., van Dokkum et al 2015;Koda et al 2015;Mihos et al 2015;Iodice et al 2020). Depending on the size metric used, such galaxies either appear as extreme outliers in the masssize relation, or show little difference from other dwarf galaxies (Chamba et al 2020), leading to the argument that a more physically motivated definition of galaxy size (based on, e.g., star formation thresholds) is called for (Trujillo et al 2020, and references therein).…”

Section: Galaxy Sizesmentioning

confidence: 99%

Stellar masses, sizes, and radial profiles for 465 nearby early-type galaxies: an extension to the Spitzer Survey of Stellar Structure in Galaxies (S$^{4}$G)

Watkins,

Salo,

Laurikainen

et al. 2022

Preprint

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Context. The Spitzer Survey of Stellar Structure in Galaxies (S 4 G) is a detailed study of over 2300 nearby galaxies in the near-infrared (NIR), which has been critical to our understanding of the detailed structures of nearby galaxies. Because the sample galaxies were selected only using radio-derived velocities, however, the survey favored late-type disk galaxies over lenticulars and ellipticals. Aims. A follow-up Spitzer survey was conducted to rectify this bias, adding 465 early-type galaxies (ETGs) to the original sample, to be analyzed in a manner consistent with the initial survey. We present the data release of this ETG extension, up to the third data processing pipeline (P3): surface photometry. Methods. We produce curves of growth and radial surface brightness profiles (with and without inclination corrections) using reduced and masked Spitzer IRAC 3.6 µm and 4.5 µm images produced through Pipelines 1 and 2, respectively. From these profiles, we derive the following integrated quantities: total magnitudes, stellar masses, concentration parameters, and galaxy size metrics. We showcase NIR scaling relations for ETGs among these quantities. Results. We examine general trends across the whole S 4 G and ETG extension among our derived parameters, highlighting differences between ETGs and late-type galaxies (LTGs). ETGs are, on average, more massive and more concentrated than LTGs, and also show subtle distinctions among ETG morphological sub-types. We also derive the following scaling relations and compare with previous results in visible light: mass-size (both half-light and isophotal), mass-concentration, mass-surface brightness (central, effective, and within 1 kpc), and mass-color. Conclusions. We find good agreement with previous works, though some relations (e.g., mass-central surface brightness) will require more careful multi-component decompositions to be fully understood. The relations between mass and isophotal radius and between mass and surface brightness within 1 kpc, in particular, show notably small scatter. The former provides important constraints on the limits of size growth in galaxies, possibly related to star formation thresholds, while the latter-particularly when paired with the similarly tight relation for LTGs-showcases the striking self-similarity of galaxy cores, suggesting these evolve little over cosmic time. All of the profiles and parameters described in this paper will be provided to the community via the NASA/IPAC database on a dedicated website.

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“…size is also mediated by the halo concentration (e.g., Desmond 2017;Jiang et al 2019;Zanisi et al 2020). Moreover, other definitions of galaxy sizes, such as 80 (Miller et al 2019) or 1 (Trujillo et al 2020), have been proposed to correlate to ℎ equally well or even better than effective radius. We will discuss these models in Appendix E.…”

Section: The Galaxy-halo Connectionmentioning

confidence: 99%

“…Therefore, we expect ,80 ≈ 4.2 . Trujillo et al (2020) and Chamba et al (2020) used deep imaging of local galaxies to define 1 as the radius that encloses the region within a physically-motivated mass surface density of 1M pc −2 (see also Sánchez Almeida 2020). Trujillo et al (2020) found that the scatter in the 1 − star relation is of the order of only ≈ 0.06 dex across five orders of magnitude, including the regime of MGs for which the relation, which is linear at lower masses, breaks.…”

Section: Appendix E: Using Other Size Estimatorsmentioning

confidence: 99%

The evolution of compact massive quiescent and star-forming galaxies derived from the Re–Rh and Mstar–Mh relations

Zanisi

Shankar

et al. 2021

Monthly Notices of the Royal Astronomical Society

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The mean size ( effective radius Re) of Massive Galaxies (MGs, Mstar > 1011.2M⊙) is observed to increase steadily with cosmic time. It is still unclear whether this trend originates from the size growth of individual galaxies (via, e.g., mergers and/or AGN feedback) or from the inclusion of larger galaxies entering the selection at later epochs (progenitor bias). We here build a data-driven, flexible theoretical framework to probe the structural evolution of MGs. We assign galaxies to dark matter haloes via stellar mass-halo mass (SMHM) relations with varying high-mass slopes and scatters σSMHM in stellar mass at fixed halo mass, and assign sizes to galaxies using an empirically-motivated, constant and linear relationship between Re and the host dark matter halo radius Rh. We find that: 1) the fast mean size growth of MGs is well reproduced independently of the shape of the input SMHM relation; 2) the numbers of compact MGs grow steadily until z ≳ 2 and fall off at lower redshifts, suggesting a lesser role of progenitor bias at later epochs; 3) a time-independent scatter σSMHM is consistent with a scenario in which compact starforming MGs transition into quiescent MGs in a few 108yr with a negligible structural evolution during the compact phase, while a scatter increasing at high redshift implies significant size growth during the starforming phase. A robust measurement of the size function of MGs at high redshift can set strong constraints on the scatter of the SMHM relation and, by extension, on models of galaxy evolution.

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A physically motivated definition for the size of galaxies in an era of ultradeep imaging

Cited by 77 publications

References 94 publications

The artemis simulations: stellar haloes of Milky Way-mass galaxies

The artemis simulations: stellar haloes of Milky Way-mass galaxies

Stellar masses, sizes, and radial profiles for 465 nearby early-type galaxies: an extension to the Spitzer Survey of Stellar Structure in Galaxies (S$^{4}$G)

The evolution of compact massive quiescent and star-forming galaxies derived from the Re–Rh and Mstar–Mh relations

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