41 research outputs found
On the Uncertainties of Stellar Mass Estimates via Colour Measurements
Mass-to-light versus colour relations (MLCRs), derived from stellar
population synthesis models, are widely used to estimate galaxy stellar masses
(M) yet a detailed investigation of their inherent biases and limitations
is still lacking. We quantify several potential sources of uncertainty, using
optical and near-infrared (NIR) photometry for a representative sample of
nearby galaxies from the Virgo cluster. Our method for combining multi-band
photometry with MLCRs yields robust stellar masses, while errors in M
decrease as more bands are simultaneously considered. The prior assumptions in
one's stellar population modelling dominate the error budget, creating a
colour-dependent bias of up to 0.6 dex if NIR fluxes are used (0.3 dex
otherwise). This matches the systematic errors associated with the method of
spectral energy distribution (SED) fitting, indicating that MLCRs do not suffer
from much additional bias. Moreover, MLCRs and SED fitting yield similar
degrees of random error (0.1-0.14 dex) when applied to mock galaxies and,
on average, equivalent masses for real galaxies with M 10
M. The use of integrated photometry introduces additional uncertainty
in M measurements, at the level of 0.05-0.07 dex. We argue that using
MLCRs, instead of time-consuming SED fits, is justified in cases with complex
model parameter spaces (involving, for instance, multi-parameter star formation
histories) and/or for large datasets. Spatially-resolved methods for measuring
M should be applied for small sample sizes and/or when accuracies less than
0.1 dex are required. An Appendix provides our MLCR transformations for ten
colour permutations of the filter set.Comment: Accepted to MNRAS. 43 pages, 12 figures, 3 table
HST-COS Spectroscopy of the Cooling Flow in Abell 1795 - Evidence for Inefficient Star Formation in Condensing Intracluster Gas
We present far-UV spectroscopy from the Cosmic Origins Spectrograph on the
Hubble Space Telescope of a cool, star-forming filament in the core of Abell
1795. These data, which span 1025A - 1700A, allow for the simultaneous modeling
of the young stellar populations and the intermediate-temperature (10^5.5 K)
gas in this filament, which is far removed (~30 kpc) from the direct influence
of the central AGN. Using a combination of UV absorption line indices and
stellar population synthesis modeling, we find evidence for ongoing star
formation, with the youngest stars having ages of 7.5 +/- 2.0 Myr and
metallicities of 0.4 +/- 0.2 Zsun. The latter is consistent with the local
metallicity of the intracluster medium. We detect the O VI (1038) line,
measuring a flux of 4.0 +/- 0.9 x 10^-17 erg s^-1 cm^-2. The O VI (1032) line
is redshifted such that it is coincident with a strong Galactic H2 absorption
feature, and is not detected. The measured O VI (1038) flux corresponds to a
cooling rate of 0.85 +/- 0.2 (stat) +/- 0.15 (sys) Msun/yr at ~10^5.5 K,
assuming that the cooling proceeds isochorically, which is consistent with the
classical X-ray luminosity-derived cooling rate in the same region. We measure
a star formation rate of 0.11 +/- 0.02 Msun/yr from the UV continuum,
suggesting that star formation is proceeding at 13 +/- 3% efficiency in this
filament. We propose that this inefficient star formation represents a
significant contribution to the larger-scale cooling flow problem.Comment: 6 pages, 4 figures. Accepted for publication in ApJ Letter
The Most Massive Ultra-Compact Dwarf Galaxy in the Virgo Cluster
We report on the properties of the most massive ultra-compact dwarf galaxy
(UCD) in the nearby Virgo Cluster of galaxies using imaging from the Next
Generation Virgo Cluster Survey (NGVS) and spectroscopy from Keck/DEIMOS. This
object (M59-UCD3) appears to be associated with the massive Virgo galaxy M59
(NGC 4621), has an integrated velocity dispersion of 78 km/s, a dynamical mass
of , and an effective radius () of 25 pc. With an
effective surface mass density of , it is the
densest galaxy in the local Universe discovered to date, surpassing the density
of the luminous Virgo UCD, M60-UCD1. M59-UCD3 has a total luminosity of
mag, and a spectral energy distribution consistent with an old
(14 Gyr) stellar population with [Fe/H]=0.0 and [/Fe]=+0.2. We also
examine deep imaging around M59 and find a broad low surface brightness stream
pointing towards M59-UCD3, which may represent a tidal remnant of the UCD
progenitor. This UCD, along with similar objects like M60-UCD1 and M59cO,
likely represents an extreme population of tidally stripped galaxies more akin
to larger and more massive compact early-type galaxies than to nuclear star
clusters in present-day dwarf galaxies.Comment: 6 pages, 4 figures, 1 table, accepted for publication in ApJ Letter
Stellar Populations and Radial Migrations in Virgo Disk Galaxies
We present stellar age profiles for 64 Virgo cluster disk galaxies whose
analysis poses a challenge for current galaxy formation models. Our results can
be summarized as follows: first, and contrary to observations of field
galaxies, these cluster galaxies are distributed almost equally amongst the
three main types of disk galaxy luminosity profiles (I/II/III), indicating that
the formation and/or survival of Type II breaks is suppressed within the
cluster environment. Second, we find examples of statistically-significant
inversions ("U-shapes") in the age profiles of all three disk galaxy types,
reminescent of predictions from high-resolution simulations of
classically-truncated Type II disks in the field. These features characterize
the age profiles for only about a third (<36%) of each disk galaxy type in our
sample. An even smaller fraction of cluster disks (~11% of the total sample),
exhibit age profiles which decrease outwards (i.e., negative age gradients).
Instead, flat and/or positive age gradients prevail (>50%) within our Type I,
II and III sub-samples. These observations thus suggest that while stellar
migrations and inside-out growth can play a significant role in the evolution
of all disk galaxy types, other factors contributing to the evolution of
galaxies can overwhelm the predicted signatures of these processes. We
interpret our observations through a scenario whereby Virgo cluster disk
galaxies formed initially like their bretheren in the field but which, upon
falling into the cluster, were transformed into their present state through
external processes linked to the environment. Current disk galaxy formation
models fail to reproduce these results, thus calling for adequate
hydrodynamical simulations of dense galaxy environments, for which the current
paper provides many constraints. [Abridged]Comment: 47 pages, 10 figures. ApJ, in press. Full resolution version
available at http://www.astro.queensu.ca/~courteau/papers/migrations2012.pd
The Formation and Evolution of Virgo Cluster Galaxies - I. Broadband Optical & Infrared Colours
We use a combination of deep optical (gri) and near-infrared (H) photometry
to study the radially-resolved colours of a broad sample of 300 Virgo cluster
galaxies. For most galaxy types, we find that the median g-H colour gradient is
either flat (gas-poor giants and gas-rich dwarfs) or negative (i.e., colours
become bluer with increasing radius; gas-poor dwarfs, spirals, and gas-poor
peculiars). Later-type galaxies typically exhibit more negative gradients than
early-types. Given the lack of a correlation between the central colours and
axis ratios of Virgo spiral galaxies, we argue that dust likely plays a small
role, if at all, in setting those colour gradients. We search for possible
correlations between galaxy colour and photometric structure or environment and
find that the Virgo galaxy colours become redder with increasing concentration,
luminosity and surface brightness, while no dependence with cluster-centric
radius or local galaxy density is detected (over a range of ~2 Mpc and ~3-16
Mpc^-2, respectively). However, the colours of gas-rich Virgo galaxies do
correlate with neutral gas deficiency, such that these galaxies become redder
with higher deficiencies. Comparisons with stellar population models suggest
that these colour gradients arise principally from variations in stellar
metallicity within these galaxies, while age variations only make a significant
contribution to the colour gradients of Virgo irregulars. A detailed stellar
population analysis based on this material is presented in Roediger et al
(2011b; arXiv:1011.3511).Comment: 34 pages, 12 figures, 1 table, submitted to MNRAS; Paper II
(arXiv:1011.3511) has also been update
The Formation and Evolution of Virgo Cluster Galaxies - II. Stellar Populations
We use a combination of deep optical and near-infrared light profiles for a
morphologically diverse sample of Virgo cluster galaxies to study the
radially-resolved stellar populations of cluster galaxies over a wide range of
galaxy structure. We find that, in the median, the age gradients of Virgo
galaxies are either flat (lenticulars and Sa-Sb spirals) or positive
(ellipticals, Sbc+Sc spirals, gas-rich dwarfs, and irregulars), while all
galaxy types have a negative median metallicity gradient. Comparison of the
galaxy stellar population diagnostics (age, metallicity, and gradients thereof)
against structural and environmental parameters also reveals that the ages of
gas-rich systems depend mainly on their atomic gas deficiencies. Conversely,
the metallicities of Virgo gas-poor galaxies depend on their concentrations,
luminosities, and surface brightnesses. The stellar population gradients of all
Virgo galaxies exhibit no dependence on either their structure or environment.
We interpret these stellar population data for Virgo galaxies in the context of
popular formation and evolution scenarios, and suggest that gas-poor giants
grew hierarchically (through dissipative starbursts), gas-poor dwarfs have
descended from at least two different production channels (e.g., environmental
transformation and merging), while spirals formed inside-out, but with star
formation in the outskirts of a significant fraction of the population having
been quenched due to ram pressure stripping. (Abridged)Comment: 54 pages, 16 figures, 3 tables, re-submitted to MNRAS (edited to
reflect the referee's suggestions