Bibcode
Leung, Gigi Y. C.; Leaman, Ryan; van de Ven, Glenn; Battaglia, Giuseppina
Bibliographical reference
Monthly Notices of the Royal Astronomical Society
Advertised on:
3
2020
Citations
25
Refereed citations
25
Description
The five globular clusters (GCs) of the Fornax dwarf spheroidal galaxy are puzzling for two reasons; the mass in GCs is high with respect to the galaxy's old stellar mass and their survival and large distance (>1 kpc) is at odds with naive expectations of dynamical friction. We present here a semi-analytic model, simultaneously addressing both problems in a comprehensive evolutionary framework for Fornax. Key to the model is inclusion of: (1) hydrodynamical constraints on the GC formation locations, (2) self-consistent velocity distribution functions in the dynamical friction calculations, and (3) expansion of GC orbits due to a past dwarf-dwarf merger in the orbit integrations. The latter is crucial for reconciling the dynamical survival of the clusters and their chemical properties with respect to the Fornax field stars. We find that in order for four of the GCs to survive at their observed projected location, a dark matter core of size rc > 1.5 kpc and a dwarf merger with dynamical mass ratio of 1:5 ≤ η ≤ 1:2 with Fornax is required. We support the merger scenario by showing that aspects of the field star metallicity distribution function and anomalous chemical properties of GC5, are representative of a merging galaxy which is ̃1/3 less massive than Fornax. Together the chemical and dynamical models suggest a scenario where three in situ GCs in proto-Fornax were ejected to the outskirts during the merger, a GC4 formed during the merger at about 10 Gyr ago, with GC5 being brought in by the merging galaxy to Fornax.
Related projects
Galaxy Evolution in the Local Group
Galaxy formation and evolution is a fundamental Astrophysical problem. Its study requires “travelling back in time”, for which there are two complementary approaches. One is to analyse galaxy properties as a function of red-shift. Our team focuses on the other approach, called “Galactic Archaeology”. It is based on the determination of galaxy
Matteo
Monelli