2,108 research outputs found

    Deep imaging of Eridanus II and its lone star cluster

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    We present deep imaging of the most distant dwarf discovered by the Dark Energy Survey, Eridanus II (Eri II). Our Magellan/Megacam stellar photometry reaches ∼\sim33 mag deeper than previous work, and allows us to confirm the presence of a stellar cluster whose position is consistent with Eri II's center. This makes Eri II, at MV=−7.1M_V=-7.1, the least luminous galaxy known to host a (possibly central) cluster. The cluster is partially resolved, and at MV=−3.5M_V=-3.5 it accounts for ∼\sim4%4\% of Eri II's luminosity. We derive updated structural parameters for Eri II, which has a half-light radius of ∼\sim280280 pc and is elongated (ϵ\epsilon∼\sim0.480.48), at a measured distance of DD∼\sim370370 kpc. The color-magnitude diagram displays a blue, extended horizontal branch, as well as a less populated red horizontal branch. A central concentration of stars brighter than the old main sequence turnoff hints at a possible intermediate-age (∼\sim33 Gyr) population; alternatively, these sources could be blue straggler stars. A deep Green Bank Telescope observation of Eri II reveals no associated atomic gas.Comment: 7 pages, 4 figures; ApJL accepte

    Antlia B: A faint dwarf galaxy member of the NGC 3109 association

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    We report the discovery of Antlia B, a faint dwarf galaxy at a projected distance of ∼\sim72 kpc from NGC 3109 (MVM_{V}∼\sim−-15 mag), the primary galaxy of the NGC 3109 dwarf association at the edge of the Local Group. The tip of the red giant branch distance to Antlia B is DD=1.29±\pm0.10 Mpc, which is consistent with the distance to NGC 3109. A qualitative analysis indicates the new dwarf's stellar population has both an old, metal poor red giant branch (≳\gtrsim10 Gyr, [Fe/H]∼\sim−-2), and a younger blue population with an age of ∼\sim200-400 Myr, analogous to the original Antlia dwarf, another likely satellite of NGC 3109. Antlia B has \ion{H}{1} gas at a velocity of vhelio,HIv_{helio,HI}=376 km s−1^{-1}, confirming the association with NGC 3109 (vheliov_{helio}=403 km s−1^{-1}). The HI gas mass (MHI_{HI}=2.8±\pm0.2×\times105^{5} M⊙_{\odot}), stellar luminosity (MVM_{V}=−-9.7±\pm0.6 mag) and half light radius (rhr_{h}=273±\pm29 pc) are all consistent with the properties of dwarf irregular and dwarf spheroidal galaxies in the Local Volume, and is most similar to the Leo P dwarf galaxy. The discovery of Antlia B is the initial result from a Dark Energy Camera survey for halo substructure and faint dwarf companions to NGC 3109 with the goal of comparing observed substructure with expectations from the Λ\Lambda+Cold Dark Matter model in the sub-Milky Way regime.Comment: 7 pages, 3 figures. Submitted to ApJ

    Calcium-Rich Gap Transients: Tidal Detonations of White Dwarfs?

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    We hypothesize that at least some of the recently discovered class of calcium-rich gap transients are tidal detonation events of white dwarfs (WDs) by black holes (BHs) or possibly neutron stars. We show that the properties of the calcium-rich gap transients agree well with the predictions of the tidal detonation model. Under the predictions of this model, we use a follow-up X-ray observation of one of these transients, SN 2012hn, to place weak upper limits on the detonator mass of this system that include all intermediate-mass BHs (IMBHs). As these transients are preferentially in the stellar haloes of galaxies, we discuss the possibility that these transients are tidal detonations of WDs caused by random flyby encounters with IMBHs in dwarf galaxies or globular clusters. This possibility has been already suggested in the literature but without connection to the calcium-rich gap transients. In order for the random flyby cross-section to be high enough, these events would have to be occurring inside these dense stellar associations. However, there is a lack of evidence for IMBHs in these systems, and recent observations have ruled out all but the very faintest dwarf galaxies and globular clusters for a few of these transients. Another possibility is that these are tidal detonations caused by three-body interactions, where a WD is perturbed toward the detonator in isolated multiple star systems. We highlight a number of ways this could occur, even in lower-mass systems with stellar-mass BHs or neutron stars. Finally, we outline several new observational tests of this scenario, which are feasible with current instrumentation.Comment: 10 pages, 1 figure, accepted for publication in MNRA
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