Your search keyword '"Willman, Beth"' showing total 5 results

1. Uncovering the orbit of the hercules dwarf galaxy.

Author

Gregory, Alexandra L, Collins, Michelle L M, Erkal, Denis, Tollerud, Erik, Delorme, Maxime, Hill, Lewis, Sand, David J, Strader, Jay, and Willman, Beth

Subjects

DWARF galaxies, ASTROMETRY, GALACTIC evolution, GALACTIC dynamics, VELOCITY, MOTION

Abstract

We present new chemo-kinematics of the Hercules dwarf galaxy based on Keck II-DEIMOS spectroscopy. Our 21 confirmed members, including 9 newly confirmed members, have a systemic velocity of v Herc = 46.4 ± 1.3 km s−1 and a velocity dispersion |$\sigma _{v,\mathrm{Herc}}=4.4^{+1.4}_{-1.2}$| km s−1, consistent with previous studies. From the strength of the Ca  ii triplet, we obtain a metallicity of [Fe/H] = −2.48 ± 0.19 dex and dispersion of |$\sigma _{\rm {[Fe/H]}}= 0.63^{+0.18}_{-0.13}$| dex. This result is within 1σ of previous measurements, and makes Hercules a particularly metal-poor galaxy, placing it slightly below the standard mass–metallicity relation. Previous photometric and spectroscopic evidence suggests that Hercules is tidally disrupting and may be on a highly radial orbit. From our identified members, we measure no significant velocity gradient. By cross-matching with the second Gaia data release, we determine an uncertainty-weighted mean proper motion of |$\mu _{\alpha }^*=\mu _{\alpha }\cos (\delta)=-0.153\pm {0.074}$| mas yr−1, μδ = −0.397 ± 0.063 mas yr−1. This proper motion is slightly misaligned with the elongation of Hercules, in contrast to models which suggest that any tidal debris should be well aligned with the orbital path. Future observations may resolve this tension. [ABSTRACT FROM AUTHOR]

Published

2020

2. The predicted luminous satellite populations around SMC- and LMC-mass galaxies - a missing satellite problem around the LMC?

Author

Dooley, Gregory A., Peter, Annika H. G., Carlin, Jeffrey L., Frebel, Anna, Bechtol, Keith, and Willman, Beth

Subjects

MAGELLANIC clouds, GALACTIC halos, DARK matter, GALACTIC evolution

Abstract

Recent discovery of many dwarf satellite galaxies in the direction of the Small and Large Magellanic Clouds (SMC and LMC) provokes questions of their origins, and what they can reveal about galaxy evolution theory. Here, we predict the satellite stellar mass function of Magellanic Cloud-mass host galaxies using abundance matching and reionization models applied to the Caterpillar simulations. Specifically focusing on the volume within 50 kpc of the LMC, we predict a mean of four to eight satellites with stellar mass M* > 104M®, and halo relationship (steep, but with an abrupt flattening at 103M®), late reionization for the Local Group (zreion ≲ 9 preferred) and/or strong tidal stripping. We can more robustly predict that ∼53 per cent of satellites within this volume were accreted together with the LMC and SMC and ∼ 47 per cent were only ever Milky Way satellites. Observing satellites of isolated LMC-sized field galaxies is essential to place the LMC in context, and to better constrain the M*-Mhalo relationship. Modelling known LMC-sized galaxies within 8Mpc, we predict 1-6 (2-12) satellites with M* > 105M® (M* > 104M®) within the virial volume of each, and 1-3 (1-7) within a single 1. ° 5 diameter field of view, making their discovery likely. [ABSTRACT FROM AUTHOR]

Published

2017

3. An observer's guide to the (Local Group) dwarf galaxies: predictions for their own dwarf satellite populations.

Author

Dooley, Gregory A., Peter, Annika H. G., Tianyi Yang, Willman, Beth, Griffen, Brendan F., and Frebel, Anna

Subjects

LOCAL Group (Astronomy), DWARF galaxies, MILKY Way

Abstract

A recent surge in the discovery of new ultrafaint dwarf satellites of the MilkyWay has inspired the idea of searching for faint satellites, 10³ M⊙ < M* < 106 M⊙, around less massive field galaxies in the Local Group. Such satellites would be subject to weaker environmental influences than MilkyWay satellites, and could lead to new insights on low-mass galaxy formation. In this paper, we predict the number of luminous satellites expected around field dwarf galaxies by applying several abundance-matching models and a reionization model to the dark-matter only Caterpillar simulation suite. For three of the four abundance-matching models used, we find a >99 per cent chance that at least one satellite with stellar mass M* > 105 M⊙ exists around the combined five Local Group field dwarf galaxies with the largest stellar mass. When considering satellites with M* > 104 M⊙, we predict a combined 5-25 satellites for the five largest field dwarfs, and 10-50 for the whole Local Group field dwarf population. Because of the relatively small number of predicted dwarfs, and their extended spatial distribution, a large fraction each Local Group dwarf's virial volume will need to be surveyed to guarantee discoveries. We compute the predicted number of satellites in a given field of view of specific Local Group galaxies, as a function of minimum satellite luminosity, and explicitly obtain such values for the Solitary Local dwarfs survey. Uncertainties in abundance-matching and reionization models are large, implying that comprehensive searches could lead to refinements of both models. [ABSTRACT FROM AUTHOR]

Published

2017

4. Dynamical evidence for a strong tidal interaction between the Milky Way and its satellite, Leo V.

Author

Collins, Michelle L. M., Tollerud, Erik J., Sand, David J., Bonaca, Ana, Willman, Beth, and Strader, Jay

Subjects

TIDES, NATURAL satellites, DWARF galaxies, DARK matter, MILKY Way

Abstract

We present a chemodynamical analysis of the Leo V dwarf galaxy, based on the Keck II DEIMOS spectra of eight member stars. We find a systemic velocity for the system of (vr) = 170.9-1.9+2.1 kms-1 and barely resolve a velocity dispersion for the system, with σvr = 2.3-1.6+3.2 kms-1, consistent with previous studies of Leo V. The poorly resolved dispersion means we are unable to adequately constrain the dark-matter content of Leo V. We find an average metallicity for the dwarf of [Fe/H] =-2.48 ± 0.21 and measure a significant spread in the iron abundance of its member stars, with -3.1 ≤ [Fe/H] ≤ -1.9 dex, which clearly identifies Leo V as a dwarf galaxy that has been able to self-enrich its stellar population through extended star formation. Owing to the tentative photometric evidence for the tidal substructure around Leo V, we also investigate whether there is any evidence for tidal stripping or shocking of the system within its dynamics. We measure a significant velocity gradient across the system, of dv/dx = -4.1-2.6+2.8 kms-1 arcmin-1 (or dv/dx = -71.9-45.6+50.8 kms-1 kpc-1), which points almost directly towards the Galactic Centre. We argue that Leo V is likely a dwarf on the brink of dissolution, having just barely survived a past encounter with the centre of the Milky Way. [ABSTRACT FROM AUTHOR]

Published

2017

5. The origin and properties of intracluster stars in a rich cluster.

Author

Willman, Beth, Governato, Fabio, Wadsley, James, and Quinn, Thomas

Subjects

*STAR clusters, *INTERSTELLAR medium, *HYDRODYNAMICS, *STELLAR luminosity function, *STAR formation, *DARK matter, *FLUID dynamics

Abstract

We use a multimillion particleN-body+ smooth particle hydrodynamics (SPH) simulation to follow the formation of a rich galaxy cluster in aΛ-cold dark matter (ΛCDM) cosmology, with the goal of understanding the origin and properties of intracluster stars. The simulation includes gas cooling, star formation, the effects of a uniform ultraviolet background and feedback from supernovae. Haloes that host galaxies as faint asare resolved by this simulation, which includes 85 per cent of the total galaxy luminosity in a rich cluster. We find that the accumulation of intracluster light (ICL) is an ongoing process, linked to infall and stripping events. The unbound star fraction varies with time between 10 and 22 per cent of the total amount of cluster stars, with an overall trend to increase with time. The fraction is 20 per cent at, consistent with observations of galaxy clusters. The surface brightness profile of the cD galaxy shows an excess compared with a de Vaucouleur profile near 200 kpc, which is also consistent with observations. Both massive and small galaxies contribute to the formation of the ICL, with stars stripped preferentially from the outer, lower-metallicity parts of their stellar distributions. Simulated observations of planetary nebulae (PNe) show significant substructure in velocity space, tracing separate streams of stripped intracluster stars. Despite an unrelaxed distribution, individual intracluster PNe might be useful mass tracers if more than five fields at a range of radii have measured line-of-sight velocities, where an accurate mass calculation depends more on the number of fields than the number of PNe measured per field. However, the orbits of intracluster stars are more anisotropic than those of galaxies or dark matter, which leads to a systematic underestimate of cluster mass relative to that calculated with galaxies, if not accounted for in dynamical models. Overall, the properties of ICL formed in a hierarchical scenario are in good agreement with current observations, supporting a model where ICL originates from the dynamical evolution of galaxies in dense environments. ICL should thus be ubiquitous in galaxy clusters. [ABSTRACT FROM AUTHOR]

Published

2004