46 research outputs found
CATS: CfAO Treasury Survey of distant galaxies, supernovae, and AGN's
The NSF Science and Technology Center for Adaptive Optics (CfAO) is
supporting a major scientific legacy project called the CfAO Treasury Survey
(CATS). CATS is obtaining near-infrared AO data in deep HST survey fields, such
as GEMS, GOODS-N, & EGS. Besides summarizing the main objectives of CATS, we
highlight some recent imaging work on the study of distant field galaxies,
AGNs, and a redshift z = 1.32 supernova. CATS plans the first data release to
the community in early 2007 (check
http://www.astro.ucla.edu/~irlab/cats/index.shtml for more details on CATS and
latest updates).Comment: 2 pages. Proceedings of the IAU Symposium 235, "Galaxy Evolution
across the Hubble Time", F. Combes & J. Palous (eds.
The Butcher-Oemler Effect at Moderate Redshift
We present the results of Butcher-Oemler-style analysis of three moderate-
redshift (0.1<z<0.2) clusters which have bimodal X-ray surface brightness
profiles. We find that at least two of these clusters exhibit unusually high
fractions of blue galaxies as compared to clusters at comparable redshifts
studied by Butcher and Oemler (1984). This implies that star formation is
occurring in a high fraction of the galaxies in the two clusters. Our results
are consistent with hierarchical clustering models in which subcluster-
subcluster mergers create shocks in the intracluster medium. The shocks, in
turn, induce simultaneous starbursts in a large fraction of cluster galaxies.
Our study therefore lends weight to the hypothesis that the Butcher-Oemler
effect is an environmental, as well as evolutionary, phenomenon.Comment: 22 pages, 8 figures; accepted for publication in A
Spectroscopic Observations of Optically Selected Clusters of Galaxies from the Palomar Distant Cluster Survey
We have conducted a redshift survey of sixteen cluster candidates from the
Palomar Distant Cluster Survey (PDCS) to determine both the density of PDCS
clusters and the accuracy of the estimated redshifts presented in the PDCS
catalog (Postman et. al. 1996). We find that the matched-filter redshift
estimate presented in the PDCS has an error sigma_z = 0.06 in the redshift
range 0.1 < z < 0.35 based on eight cluster candidates with three or more
concordant galaxy redshifts.
We measure the low redshift (0.1 < z < 0.35) space density of PDCS clusters
to be 31.3^{+30.5}_{-17.1} * E-06 h^3 Mpc^-3 (68% confidence limits for a
Poisson distribution) for Richness Class 1 systems. We find a tentative space
density of 10.4^{+23.4}_{-8.4}* E-06 h^3 Mpc^-3 for Richness Class 2 clusters.
These densities compare favorably with those found for the whole of the PDCS
and support the finding that the space density of clusters in the PDCS is a
factor of ~5 above that of clusters in the Abell catalog (Abell 1958; Abell,
Corwin, and Olowin 1989). These new space density measurements were derived as
independently as possible from the original PDCS analysis and therefore,
demonstrate the robustness of the original work. Based on our survey, we
conclude that the PDCS matched-filter algorithm is successful in detecting real
clusters and in estimating their true redshifts in the redshift range we
surveyed.Comment: 23 pages with 4 figures and 3 seperate tables. To be published in the
November Issue of the Astronomical Journa
Triggered or Self-Regulated Star Formation within Intermediate Redshift Luminous Infrared Galaxies (I). Morphologies and Spatially Resolved Spectral Energy Distributions
We imaged a set of 15 intermediate redshift (z~0.8) luminous infrared
galaxies (LIRGs) with the Keck Laser Guide Star (LGS) AO facility. These
galaxies were selected from the GOODS-S field, allowing us to combine the high
spatial resolution HST optical (B, V, i, and z-bands) images with our
near-infrared (K'-band) images to study the LIRG morphologies and spatially
resolved spectral energy distributions (SEDs). Two thirds of the LIRGs are disk
galaxies, with only one third showing some evidence for interactions, minor, or
major mergers. In contrast with local LIRG disks (which are primarily barred
systems), only 10% of the LIRG disks in our sample contain a prominent bar.
While the optical bands tend to show significant point-like substructure,
indicating distributed star formation, the AO K-band images tend to be smooth.
The SEDs of the LIRGs are consistent with distributed dusty star formation, as
exhibited by optical to IR colors redder than allowed by old stellar
populations alone. This effect is most pronounced in the galaxy cores, possibly
indicating central star formation. We also observed a set of 11 intermediate
redshift comparison galaxies, selected to be non-ellipticals with apparent
K-band magnitudes comparable to the LIRGs. The "normal" (non-LIRG) systems
tended to have lower optical luminosity, lower stellar mass, and more irregular
morphology than the LIRGs. Half of the "normal" galaxies have SEDs consistent
with intermediate aged stellar populations and minimal dust. The other half
show evidence for some dusty star formation, usually concentrated in their
cores. Our work suggests that the LIRG disk galaxies are similar to large disk
systems today, undergoing self regulated star formation, only at 10 - 20 times
higher rates. (Abridged)Comment: Accepted for Publication in AJ. 27 pages, 21 figures, 3 table
The Bright SHARC Survey: The Cluster Catalog
We present the Bright SHARC (Serendipitous High-Redshift Archival ROSAT
Cluster) Survey, which is an objective search for serendipitously detected
extended X-ray sources in 460 deep ROSAT PSPC pointings. The Bright SHARC
Survey covers an area of 178.6 sq.deg and has yielded 374 extended sources. We
discuss the X-ray data reduction, the candidate selection and present results
from our on-going optical follow-up campaign. The optical follow-up
concentrates on the brightest 94 of the 374 extended sources and is now 97%
complete. We have identified thirty-seven clusters of galaxies, for which we
present redshifts and luminosities. The clusters span a redshift range of
0.0696<z<0.83 and a luminosity range of 0.065<Lx<8.3e44 erg/s [0.5-2.0 keV]
(assuming Ho = 50 km/s/Mpc and qo=0.5). Twelve of the clusters have redshifts
greater than z=0.3, eight of which are at luminosities brighter than Lx=3e44
erg/s. Seventeen of the 37 optically confirmed Bright SHARC clusters have not
been listed in any previously published catalog. We also report the discovery
of three candidate ``fossil groups'' of the kind proposed by Ponman et al.
(1994).Comment: Minor revisions: References updated and typos corrected. Shortened by
use of emulateapj.st
The Evolution of Galaxy Mergers and Morphology at z<1.2 in the Extended Groth Strip
We present the quantitative rest-frame B morphological evolution and galaxy
merger fractions at 0.2 < z < 1.2 as observed by the All-wavelength Extended
Groth Strip International Survey (AEGIS). We use the Gini coefficent and M_20
to identify major mergers and classify galaxy morphology for a volume-limited
sample of 3009 galaxies brighter than 0.4 L_B^*, assuming pure luminosity
evolution of 1.3 M_B per unit redshift. We find that the merger fraction
remains roughly constant at 10 +/- 2% for 0.2 < z < 1.2. The fraction of
E/S0/Sa increases from 21+/- 3% at z ~ 1.1 to 44 +/- 9% at z ~ 0.3, while the
fraction of Sb-Ir decreases from 64 +/- 6% at z ~ 1.1 to 47 +/- 9% at z ~ 0.3.
The majority of z 10^11 L_sun
are disk galaxies, and only ~ 15% are classified as major merger candidates.
Edge-on and dusty disk galaxies (Sb-Ir) are almost a third of the red sequence
at z ~ 1.1, while E/S0/Sa makeup over 90% of the red sequence at z ~ 0.3.
Approximately 2% of our full sample are red mergers. We conclude (1) the galaxy
merger rate does not evolve strongly between 0.2 < z < 1.2; (2) the decrease in
the volume-averaged star-formation rate density since z ~ 1 is a result of
declining star-formation in disk galaxies rather than a disappearing population
of major mergers; (3) the build-up of the red sequence at z < 1 can be
explained by a doubling in the number of spheroidal galaxies since z ~ 1.2.Comment: 24 pages, including 3 tables and 18 color figures; accepted to the
Astrophysical Journal; high resolution version available at
http://www.noao.edu/noao/staff/lotz/lotz_mergers.pd