140 research outputs found
Chemical enrichment in very low-metallicity environments: Bootes I
We present different chemical evolution models for the ultrafaint dwarf
galaxy Bootes I. We either assume that the galaxy accretes its mass through
smooth infall of gas of primordial chemical composition (classical models) or
adopt mass accretion histories derived from the combination of merger trees
with semi-analytical modelling (cosmologically-motivated models). Furthermore,
we consider models with and without taking into account inhomogeneous mixing in
the ISM within the galaxy. The theoretical predictions are then compared to
each other and to the body of the available data. From this analysis, we
confirm previous findings that Bootes I has formed stars with very low
efficiency but, at variance with previous studies, we do not find a clear-cut
indication that supernova explosions have sustained long-lasting galactic-scale
outflows in this galaxy. Therefore, we suggest that external mechanisms such as
ram pressure stripping and tidal stripping are needed to explain the absence of
neutral gas in Bootes I today.Comment: 13 pages, 11 figures, accepted for publication in MNRA
The Bifurcated Age-Metallicity Relation of Milky Way Globular Clusters and its Implications For the Accretion History of the Galaxy
We use recently derived ages for 61 Milky Way (MW) globular clusters (GCs) to
show that their age-metallicity relation (AMR) can be divided into two
distinct, parallel sequences at [Fe/H] \ga -1.8. Approximately one-third of
the clusters form an offset sequence that spans the full range in age (--13 Gyr), but is more metal rich at a given age by dex in
[Fe/H]. All but one of the clusters in the offset sequence show orbital
properties that are consistent with membership in the MW disk. They are not
simply the most metal-rich GCs, which have long been known to have disk-like
kinematics, but they are the most metal-rich clusters at all ages. The slope of
the mass-metallicity relation (MMR) for galaxies implies that the offset in
metallicity of the two branches of the AMR corresponds to a mass decrement of 2
dex, suggesting host galaxy masses of M_{*} \sim 10^{7-8} \msol for GCs that
belong to the more metal-poor AMR. We suggest that the metal-rich branch of the
AMR consists of clusters that formed in-situ in the disk, while the metal-poor
GCs were formed in relatively low-mass (dwarf) galaxies and later accreted by
the MW. The observed AMR of MW disk stars, and of the LMC, SMC and WLM dwarf
galaxies are shown to be consistent with this interpretation, and the relative
distribution of implied progenitor masses for the halo GC clusters is in
excellent agreement with the MW subhalo mass function predicted by simulations.
A notable implication of the bifurcated AMR, is that the identical mean ages
and spread in ages, for the metal rich and metal poor GCs are difficult to
reconcile with an in-situ formation for the latter population.Comment: 16 pages, 9 figures, accepted for publication in MNRA
On the link between nuclear star cluster and globular cluster system mass, nucleation fraction and environment
We present a simple model for the host mass dependence of the galaxy
nucleation fraction (), the galaxy's nuclear star cluster (NSC) mass
and the mass in its surviving globular clusters (). Considering the
mass and orbital evolution of a GC in a galaxy potential, we define a critical
mass limit () above which a GC can simultaneously in-spiral to the
galaxy centre due to dynamical friction and survive tidal dissolution, to build
up the NSC. The analytic expression for this threshold mass allows us to model
the nucleation fraction for populations of galaxies. We find that the slope and
curvature of the initial galaxy size-mass relation is the most important factor
(with the shape of the GC mass function a secondary effect) setting the
fraction of galaxies that are nucleated at a given mass. The well defined
skew-normal observations in galaxy cluster populations are
naturally reproduced in these models, provided there is an inflection in the
{initial} size-mass relation at . Our
analytic model also predicts limits to the and relations which bound the scatter of the observational data.
Moreoever, we illustrate how these scaling relations and vary if the
star cluster formation efficiency, GC mass function, galaxy environment or
galaxy size-mass relation are altered. Two key predictions of our model are: 1)
galaxies with NSC masses greater than their GC system masses are more compact
at fixed stellar mass, and 2) the fraction of nucleated galaxies at fixed
galaxy mass is higher in denser environments. That a single model framework can
reproduce both the NSC and GC scaling relations provides strong evidence that
GC in-spiral is an important mechanism for NSC formation.Comment: 17 pages, 20 figures. Accepted for publication in MNRA
Backflow Relief Valve Test Stand
This Final Design Review (FDR) document details the final design, manufacturing, testing, and results of the Zurn Wilkins Backflow Relief Valve Test Stand Project under the sponsorship of Brian Yale and Rueben Westmoreland. This project involves simulating real-world conditions of static pressure and water hammer cycling. The stand will give Zurn Wilkins’ engineers a method by which to test their relief valves prior to a rigorous, yearlong University of Southern California (USC) testing procedure. Our design involves using city water, a pump, a Zurn backflow preventer, and a control system to apply specific pressures to each end of the relief valves and allow for automatic pressure cycling. Various manufacturing methods were used to create the final verification prototype, particularly welding and assembling brass piping. The final stand design was tested to determine if the test cycles work, and it was discovered that static pressure cycling functions as desired. However, the water hammer cycling did not produce the pressure spikes outlined in the engineering specifications. Although the water hammer cycle did not work, the stand interfaces with the current relief valves at Zurn Wilkins and will still be useful for testing the relief valves prior to the USC tests
A dynamical view on stellar metallicity gradient diversity across the Hubble sequence with CALIFA
We analyze radial stellar metallicity and kinematic profiles out to 1Re in
244 CALIFA galaxies ranging from morphological type E to Sd, to study the
evolutionary mechanisms of stellar population gradients. We find that linear
metallicity gradients exhibit a clear correlation with galaxy morphological
type - with early type galaxies showing the steepest gradients. We show that
the metallicity gradients simply reflect the local mass-metallicity relation
within a galaxy. This suggests that the radial stellar population distribution
within a galaxys effective radius is primarily a result of the \emph{in-situ}
local star formation history. In this simple picture, the dynamically derived
stellar surface mass density gradient directly predicts the metallicity
gradient of a galaxy. We show that this correlation and its scatter can be
reproduced entirely by using independent empirical galaxy structural and
chemical scaling relations. Using Schwarzschild dynamical models, we also
explore the link between a galaxys local stellar populations and their orbital
structures. We find that galaxies angular momentum and metallicity gradients
show no obvious causal link. This suggests that metallicity gradients in the
inner disk are not strongly shaped by radial migration, which is confirmed by
the lack of correlation between the metallicity gradients and observable probes
of radial migration in the galaxies, such as bars and spiral arms. Finally, we
find that galaxies with positive metallicity gradients become increasingly
common towards low mass and late morphological types - consistent with stellar
feedback more efficiently modifying the baryon cycle in the central regions of
these galaxies.Comment: 20 pages, 13 figure
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