A Rich Globular Cluster System in Dragonfly 17: Are Ultra-Diffuse Galaxies Pure Stellar Halos?*

Peng, Eric W.; Lim, Sungsoon

doi:10.3847/2041-8205/822/2/l31

Cited by 123 publications

(166 citation statements)

References 38 publications

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“…HR17 used weak lensing results to connect their measured stellar masses to halo masses (M 200 ) and virial radii (R 200 (Peng et al 2016), and assign approximate virial radii of 130 and 175 kpc respectively. The four most massive galaxies in our sample lack halo masses and virial radii.…”

Section: Resultsmentioning

confidence: 99%

How large are the globular cluster systems of early-type galaxies and do they scale with galaxy halo properties?

Forbes

2017

Monthly Notices of the Royal Astronomical Society: Letters

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The globular cluster systems of galaxies are well-known to extend to large galactocentric radii. Here we quantify the size of GC systems using the half number radius of 22 GC systems around early-type galaxies from the literature. We compare GC system sizes to the sizes and masses of their host galaxies. We find that GC systems typically extend to 4× that of the host galaxy size, however this factor varies with galaxy stellar mass from about 3× for M * galaxies to 5× for the most massive galaxies in the universe. The size of a GC system scales approximately linearly with the virial radius (R 200 ) and with the halo mass (M 200 ) to the 1/3 power. The GC system of the Milky Way follows the same relations as for early-type galaxies. For Ultra Diffuse Galaxies their GC system size scales with halo mass and virial radius as for more massive, larger galaxies. UDGs indicate that the linear scaling of GC system size with stellar mass for massive galaxies flattens out for low stellar mass galaxies. Our scalings are different to those reported recently by Hudson & Robison (2017).

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Section: Resultsmentioning

confidence: 99%

How large are the globular cluster systems of early-type galaxies and do they scale with galaxy halo properties?

Forbes

2017

Monthly Notices of the Royal Astronomical Society: Letters

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“…On the other hand, the recent discovery of "ultra-diffuse" galaxies (UDGs) in large galaxy clusters (van Dokkum et al 2015;Koda et al 2015;Mihos et al 2015;Muñoz et al 2015;Martínez-Delgado et al 2016) have been proposed to represent failed L * galaxies with deep potentials relative to their stellar masses. Little is known about their respective GC systems, but recent work has indicated that they may have high SN 30 with as many as dozens of GCs (Beasley & Trujillo 2016;Peng & Lim 2016;van Dokkum et al 2016). These works find that UDGs are likely to host primarily blue GC populations more similar to dwarfs than giants, although with only one UDG GC system studied so far, few general conclusions can be drawn.…”

Section: The Extreme Halo Of Ngc 5128 and Its Gc Systemmentioning

confidence: 99%

The Survey of Centaurus A's Baryonic Structures (SCABS) – II. The extended globular cluster system of NGC 5128 and its nearby environment

Taylor

Puzia

Muñoz

et al. 2017

Monthly Notices of the Royal Astronomical Society

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New wide-field u g r i z Dark Energy Camera observations centred on the nearby giant elliptical galaxy NGC 5128 covering ∼ 21 deg 2 are used to compile a new catalogue of ∼ 3 200 globular clusters (GCs). We report 2 404 newly identified candidates, including the vast majority within ∼ 140 kpc of NGC 5128. We find evidence for a transition at a galactocentric radius of R gc ≈ 55 kpc from GCs "intrinsic" to NGC 5128 to those likely to have been accreted from dwarf galaxies or that may transition to the intragroup medium of the Centaurus A galaxy group. We fit power-law surface number density profiles of the form Σ N,Rgc ∝ R Γ gc and find that inside the transition radius, the red GCs are more centrally concentrated than the blue, with Γ inner,red ≈ −1.78 and Γ inner,blue ≈ −1.40, respectively. Outside this region both profiles flatten, more dramatically for the red GCs (Γ outer,red ≈ −0.33) compared to the blue (Γ outer,blue ≈ −0.61), although the former is more likely to suffer contamination by background sources. The median (g −z ) 0 = 1.27 mag colour of the inner red population is consistent with arising from the amalgamation of two giant galaxies each less luminous than present-day NGC 5128. Both in-and out-ward of the transition radius, we find the fraction of blue GCs to dominate over the red GCs, indicating a lively history of minormergers. Assuming the blue GCs to originate primarily in dwarf galaxies, we model the population required to explain them, while remaining consistent with NGC 5128's present-day spheroid luminosity. We find that that several dozen dwarfs of luminosities L dw,V 10 6−9.3 L V, , following a Schechter luminosity function with a faint-end slope of −1.50 α −1.25 is favoured, many of which may have already been disrupted in NGC 5128's tidal field.

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“…Using the abundance and kinematics of globular clusters around two UDGs, VCC 1287 and DF17, and Beasley & Trujillo (2016) estimated the corresponding dynamical masses to be around m vir ∼ (8 ± 4) × 10 10 M and m vir ∼ (9 ± 2) × 10 10 M , respectively, similar to that of the typical dwarf galaxies. Using the relation between the mass of the globular cluster system and the halo mass (Harris, Harris & Alessi 2013;Harris, Harris & Hudson 2015), Peng & Sungsoon (2016) also inferred the total mass of DF17 to be (9.3 ± 4.7) × 10 10 M ; Amorisco, Monachesi & White (2016) estimated the dynamical masses of 54 Coma UDGs to be lower than 1.3 × 10 11 M . Román & Trujillo (2017a) also found that the distribution of UDGs around A168 is similar to the normal dwarfs, but significantly different from the distribution of massive galaxies with masses similar to the Milky Way.…”

Section: Introductionmentioning

confidence: 99%

A Universe of ultradiffuse galaxies: theoretical predictions from ΛCDM simulations

Guo

Gao

et al. 2017

Monthly Notices of the Royal Astronomical Society

124

138

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A particular population of galaxies have drawn much interest recently, which are as faint as typical dwarf galaxies but have the sizes as large as L * galaxies, the so called ultra-diffuse galaxies (UDGs). The lack of tidal features of UDGs in dense environments suggests that their host halos are perhaps as massive as that of the Milky Way. On the other hand, galaxy formation efficiency should be much higher in the halos of such masses. Here we use the model galaxy catalog generated by populating two large simulations: the Millennium-II cosmological simulation and Phoenix simulations of 9 big clusters with the semi-analytic galaxy formation model. This model reproduces remarkably well the observed properties of UDGs in the nearby clusters, including the abundance, profile, color, and morphology, etc. We search for UDG candidates using the public data and find 2 UDG candidates in our Local Group and 23 in our Local Volume, in excellent agreement with the model predictions. We demonstrate that UDGs are genuine dwarf galaxies, formed in the halos of ∼ 10 10 M . It is the combination of the late formation time and high-spins of the host halos that results in the spatially extended feature of this particular population. The lack of tidal disruption features of UDGs in clusters can also be explained by their late infall-time.

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A Rich Globular Cluster System in Dragonfly 17: Are Ultra-Diffuse Galaxies Pure Stellar Halos?*

Cited by 123 publications

References 38 publications

How large are the globular cluster systems of early-type galaxies and do they scale with galaxy halo properties?

How large are the globular cluster systems of early-type galaxies and do they scale with galaxy halo properties?

The Survey of Centaurus A's Baryonic Structures (SCABS) – II. The extended globular cluster system of NGC 5128 and its nearby environment

A Universe of ultradiffuse galaxies: theoretical predictions from ΛCDM simulations

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