52 research outputs found
The Rarity of Star Formation in Brightest Cluster Galaxies as Measured by WISE
We present the mid-infrared (IR) star formation rates of 245 X-ray selected,
nearby (z<0.1) brightest cluster galaxies (BCGs). A homogeneous and volume
limited sample of BCGs was created by X-ray selecting clusters with L_x >
1x10^44 erg/s. The Wide-Field Infrared Survey Explorer (WISE) AllWISE Data
Release provides the first measurement of the 12 micron star formation
indicator for all BCGs in the nearby Universe. Perseus A and Cygnus A are the
only galaxies in our sample to have star formation rates of > 40 M_sol/yr,
indicating that these two galaxies are highly unusual at current times. Stellar
populations of 99 +/- 0.6 % of local BCGs are (approximately) passively
evolving, with star formation rates of <10 M_sol/yr. We find that in general,
star formation produces only modest BCG growth at the current epoch.Comment: 5 pages, 3 figures, accepted for publication in MNRA
The many assembly histories of massive void galaxies as revealed by integral field spectroscopy
We present the first detailed integral field spectroscopy study of nine central void galaxies with M*>10¹⁰Mʘ using the Wide Field Spectrograph to determine how a range of assembly histories manifest themselves in the current day Universe.While the majority of these galaxies are evolving secularly, we find a range of morphologies, merger histories and stellar population distributions, though similarly low Hα-derived star formation rates (10¹⁰Mʘ have similarly low star formation rates
From the outside looking in: what can Milky Way Analogues tell us about the star formation rate of our own galaxy?
The Milky Way has been described as an anaemic spiral, but is its star formation rate (SFR) unusually low when compared to its peers? To answer this question, we define a sample of Milky Way Analogues (MWAs) based on stringent cuts on the best literature estimates of non-transient structural features for the Milky Way. This selection yields only 176 galaxies from the whole of the SDSS DR7 spectroscopic sample which have morphological classifications in GZ2, from which we infer SFRs from two separate indicators. The mean SFRs found are log(SFR SED /M yr −1) = 0.53 with a standard deviation of 0.23 dex from SED fits, and log(SFR W4 /M yr −1) = 0.68 with a standard deviation of 0.41 dex from a mid-infrared calibration. The most recent estimate for the Milky Way's star formation rate of log(SFR MW /M yr −1) = 0.22 fits well within 2σ of these values, where σ is the standard deviation of each of the SFR indicator distributions. We infer that the Milky Way, while being a galaxy with a somewhat low SFR, is not unusual when compared to similar galaxies
A photometrically and spectroscopically confirmed population of passive spiral galaxies
We have identified a population of passive spiral galaxies from photometry and integral field spectroscopy. We selected z < 0.035 spiral galaxies that have WISE colours consistent with little mid-infrared emission from warm dust. Matched aperture photometry of 51 spiral galaxies in ultraviolet, optical and mid-infrared show these galaxies have colours consistent with passive galaxies. Six galaxies form a spectroscopic pilot study and were observed using the Wide-Field Spectrograph to check for signs of nebular emission from star formation. We see no evidence of substantial nebular emission found in previous red spiral samples. These six galaxies possess absorption-line spectra with 4000 Å breaks consistent with an average luminosity-weighted age of 2.3 Gyr. Our photometric and integral field spectroscopic observations confirm the existence of a population of local passive spiral galaxies, implying that transformation into early-type morphologies is not required for the quenching of star formation
Multiple mechanisms quench passive spiral galaxies
We examine the properties of a sample of 35 nearby passive spiral galaxies in order to determine their dominant quenching mechanism(s). All five low-mass (M⋆ < 1 × 1010 M⊙) passive spiral galaxies are located in the rich Virgo cluster. This is in contrast to low-mass spiral galaxies with star formation, which inhabit a range of environments. We postulate that cluster-scale gas stripping and heating mechanisms operating only in rich clusters are required to quench low-mass passive spirals, and ram-pressure stripping and strangulation are obvious candidates. For higher mass passive spirals, while trends are present, the story is less clear. The passive spiral bar fraction is high: 74 ± 15 per cent, compared with 36 ± 5 per cent for a mass, redshift and T-type matched comparison sample of star-forming spiral galaxies. The high mass passive spirals occur mostly, but not exclusively, in groups, and can be central or satellite galaxies. The passive spiral group fraction of 74 ± 15 per cent is similar to that of the comparison sample of star-forming galaxies at 61 ± 7 per cent. We find evidence for both quenching via internal structure and environment in our passive spiral sample, though some galaxies have evidence of neither. From this, we conclude no one mechanism is responsible for quenching star formation in passive spiral galaxies – rather, a mixture of mechanisms is required to produce the passive spiral distribution we see today
HI galaxies with little star formation: an abundance of LIERs
We present a sample of 91 HI galaxies with little or no star formation and
discuss the analysis of the integral field unit (IFU) spectra of 28 of these
galaxies. We identified HI galaxies from the HI Parkes All-Sky Survey Catalog
(HICAT) with Wide-field Infrared Survey Explorer (WISE) colours consistent with
low specific star formation (< 10 yr), and obtained optical
IFU spectra with the Wide-Field Spectrograph (WiFeS). Visual inspection of the
PanSTARRS, Dark Energy Survey, and Carnegie-Irvine imaging of 62 galaxies
reveals that at least 32 galaxies in the sample have low levels of star
formation, primarily in arms/rings. New IFU spectra of 28 of these galaxies
reveal 3 galaxies with central star formation, 1 galaxy with low-ionisation
nuclear emission-line regions (LINERs), 20 with extended low-ionisation
emission-line regions (LIERs) and 4 with high excitation Seyfert (Sy) emission.
From the spectroscopic analysis of HI-selected galaxies with little star
formation, we conclude that 75% of this population are LINERs/LIERs
Ageing and Quenching through the ageing diagram II: physical characterization of galaxies
The connection between quenching mechanisms, which rapidly turn star-forming
systems into quiescent, and the properties of the galaxy population remains
difficult to discern. In this work we investigate the physical properties of
MaNGA and SAMI galaxies at different stages of their star formation history.
Specifically, we compare galaxies with signatures of recent quenching
(Quenched) -- in absorption and low -- with the
rest of the low star-forming and active population (Retired and Ageing,
respectively). The analysis is performed in terms of characteristics such as
the total stellar mass, half-light radius, velocity-to-dispersion ratio,
metallicity, and environment. We find that the Ageing population comprises a
heterogeneous mixture of galaxies, preferentially late-type systems, with
diverse physical properties. Retired galaxies, formerly Ageing or Quenched
systems, are dominated by early-type high-mass galaxies found both at low and
dense environments. Most importantly, we find that recently quenched galaxies
are consistent with a population of compact low-mass satellite systems, with
higher metallicities than their Ageing analogues. We argue that this is
compatible with being quenched after undergoing a star-burst phase induced by
environmental processes (e.g. ram pressure). However, we also detect a
non-negligible fraction of field central galaxies likely quenched by internal
processes. This study highlights that, in order to constrain the mechanisms
driving galaxy evolution, it is crucial to distinguish between old (Retired)
and recently quenched galaxies, thus requiring at least two estimates of the
specific star formation rate over different timescales.Comment: Accepted for publication in MNRA
HI Rich but Low Star Formation galaxies in MaNGA: Physical Properties and Comparison to Control Samples
Gas rich galaxies are typically star-forming. We make use of HI-MaNGA, a
program of HI follow-up for the Mapping Nearby Galaxies at Apache Point
Observatory (MaNGA) survey of the Sloan Digital Sky Surveys to construct a
sample of unusual neutral hydrogen (HI, 21cm) rich galaxies which have low Star
Formation Rates (SFRs); using infra-red color from the Wide-field Infrared
Survey Explorer (WISE) as a proxy for specific SFR. Out of a set of 1575 MaNGA
galaxies with HI-MaNGA detections, we find 83 (5%) meet our selection criteria
to be HI rich with low SFR. We construct two stellar mass-matched control
samples: HI rich galaxies with typical SFR (High SF Control) and HI poor
galaxies with low SFR (Low HI Control). We investigate the properties of each
of these samples, comparing physical parameters such as ionization state maps,
stellar and ionized gas velocity and dispersion, environment measures,
metallicity, and morphology to search for the reasons why these unusual HI rich
galaxies are not forming stars. We find evidence for recent external accretion
of gas in some galaxies (via high counter-rotating fractions), along with some
evidence for AGN feedback (from a high cLIER and/or red geyser fraction), and
bar quenching (via an enhanced strong bar fraction). Some galaxies in the
sample are consistent with simply having their HI in a high angular momentum,
large radius, low density disc. We conclude that no single physical process can
explain all HI rich, low SFR galaxies.Comment: 15 pages, in press MNRAS. v2 following corrections noticed in proof
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