28 research outputs found
Galactic winds and stellar populations in Lyman emitting galaxies at z ~ 3.1
We present a sample of 33 spectroscopically confirmed z ~ 3.1
Ly-emitting galaxies (LAEs) in the Cosmological Evolution Survey
(COSMOS) field. This paper details the narrow-band survey we conducted to
detect the LAE sample, the optical spectroscopy we performed to confirm the
nature of these LAEs, and a new near-infrared spectroscopic detection of the [O
III] 5007 \AA\ line in one of these LAEs. This detection is in addition to two
[O III] detections in two z ~ 3.1 LAEs we have reported on previously (McLinden
et al 2011). The bulk of the paper then presents detailed constraints on the
physical characteristics of the entire LAE sample from spectral energy
distribution (SED) fitting. These characteristics include mass, age,
star-formation history, dust content, and metallicity. We also detail an
approach to account for nebular emission lines in the SED fitting process -
wherein our models predict the strength of the [O III] line in an LAE spectrum.
We are able to study the success of this prediction because we can compare the
model predictions to our actual near-infrared observations both in galaxies
that have [O III] detections and those that yielded non-detections. We find a
median stellar mass of 6.9 10 M and a median star
formation rate weighted stellar population age of 4.5 10 yr. In
addition to SED fitting, we quantify the velocity offset between the [O III]
and Ly lines in the galaxy with the new [O III] detection, finding that
the Ly line is shifted 52 km s redwards of the [O III] line,
which defines the systemic velocity of the galaxy.Comment: 38 pages, 27 figures, 4 tables, Accepted for publication in MNRA
The Dynamical Masses, Densities, and Star Formation Scaling Relations of Lyman Alpha Galaxies
We present the first dynamical mass measurements for Lyman alpha galaxies at
high redshift, based on velocity dispersion measurements from rest-frame
optical emission lines and size measurements from HST imaging, for a sample of
nine galaxies drawn from four surveys. These measurements enable us to study
the nature of Lyman alpha galaxies in the context of galaxy scaling relations.
The resulting dynamical masses range from 1e9 to 1e10 solar masses. We also fit
stellar population models to our sample, and use them to plot the Lyman alpha
sample on a stellar mass vs. line width relation. Overall, the Lyman alpha
galaxies follow well the scaling relation established by observing star forming
galaxies at lower redshift (and without regard for Lyman alpha emission),
though in 1/3 of the Lyman alpha galaxies, lower-mass fits are also acceptable.
In all cases, the dynamical masses agree with established stellarmass-linewidth
relation. Using the dynamical masses as an upper limit on gas mass, we show
that Lyman alpha galaxies resemble starbursts (rather than "normal" galaxies)
in the relation between gas mass surface density and star formation activity,
in spite of relatively modest star formation rates. Finally, we examine the
mass densities of these galaxies, and show that their future evolution likely
requires dissipational ("wet") merging. In short, we find that Lyman alpha
galaxies are low mass cousins of larger starbursts.Comment: Submitted to The Astrophysical Journal. 23 pp including three figures
and four table
The distribution of satellites around massive galaxies at 1<z<3 in ZFOURGE/CANDELS: dependence on star formation activity
We study the statistical distribution of satellites around star-forming and
quiescent central galaxies at 1<z<3 using imaging from the FourStar Galaxy
Evolution Survey (ZFOURGE) and the Cosmic Assembly Near-IR Deep Extragalactic
Legacy Survey (CANDELS). The deep near-IR data select satellites down to
at z<3. The radial satellite distribution around centrals
is consistent with a projected NFW profile. Massive quiescent centrals,
, have 2 times the number of satellites compared
to star-forming centrals with a significance of 2.7 even after
accounting for differences in the centrals' stellar-mass distributions. We find
no statistical difference in the satellite distributions of intermediate-mass
quiescent and star-forming centrals, . Comparing
to the Guo2011 semi-analytic model, the excess number of satellites indicates
that quiescent centrals have halo masses 0.3 dex larger than star-forming
centrals, even when the stellar-mass distributions are fixed. We use a simple
toy model that relates halo mass and quenching, which roughly reproduces the
observed quenched fractions and the differences in halo mass between
star-forming and quenched galaxies only if galaxies have a quenching
probability that increases with halo mass from 0 for
11 to 1 for 13.5. A single
halo-mass quenching threshold is unable to reproduce the quiescent fraction and
satellite distribution of centrals. Therefore, while halo quenching may be an
important mechanism, it is unlikely to be the only factor driving quenching. It
remains unclear why a high fraction of centrals remain star-forming even in
relatively massive halos.Comment: 19 pages, 17 figures, accepted by ApJ. Information on ZFOURGE can be
found at http://zfourge.tamu.ed
The Relation Between SFR and Stellar Mass for Galaxies at 3.5 6.5 in CANDELS
Distant star-forming galaxies show a correlation between their star formation
rates (SFR) and stellar masses, and this has deep implications for galaxy
formation. Here, we present a study on the evolution of the slope and scatter
of the SFR-stellar mass relation for galaxies at using
multi-wavelength photometry in GOODS-S from the Cosmic Assembly Near-infrared
Deep Extragalactic Legacy Survey (CANDELS) and Spitzer Extended Deep Survey. We
describe an updated, Bayesian spectral-energy distribution fitting method that
incorporates effects of nebular line emission, star formation histories that
are constant or rising with time, and different dust attenuation prescriptions
(starburst and Small Magellanic Cloud). From =6.5 to =3.5 star-forming
galaxies in CANDELS follow a nearly unevolving correlation between stellar mass
and SFR that follows SFR with at and at . This evolution requires a star formation
history that increases with decreasing redshift (on average, the SFRs of
individual galaxies rise with time). The observed scatter in the SFR-stellar
mass relation is tight, yr 0.4 dex, for galaxies with dex.
Assuming that the SFR is tied to the net gas inflow rate (SFR
), then the scatter in the gas inflow rate is also
smaller than 0.30.4 dex for star-forming galaxies in these stellar mass and
redshift ranges, at least when averaged over the timescale of star formation.
We further show that the implied star formation history of objects selected on
the basis of their co-moving number densities is consistent with the evolution
in the SFR-stellar mass relation.Comment: 31 pages, 24 figures, accepted for publication in Ap
The Evolution of the Galaxy Rest-Frame Ultraviolet Luminosity Function Over the First Two Billion Years
We present a robust measurement and analysis of the rest-frame ultraviolet
(UV) luminosity function at z=4-8. We use deep Hubble Space Telescope imaging
over the CANDELS/GOODS fields, the Hubble Ultra Deep Field and the Year 1
Hubble Frontier Field deep parallel observations. These surveys provides an
effective volume of 0.6-1.2 x 10^6 Mpc^3 over this epoch, allowing us to
perform a robust search for faint (M_UV=-18) and bright (M_UV < -21) galaxies.
We select candidate galaxies using a well-tested photometric redshift technique
with careful screening of contaminants, finding a sample of 7446 galaxies at
3.51000 galaxies at z~6-8. We measure the luminosity function
using a Markov Chain Monte Carlo analysis to measure robust uncertainties. At
the faint end our results agree with previous studies, yet we find a higher
abundance of UV-bright galaxies at z>6, with M* ~ -21 at z>5, different than
that inferred based on previous trends at lower redshift. At z=8, a single
power-law provides an equally good fit to the UV luminosity function, while at
z=6 and 7, an exponential cutoff at the bright-end is moderately preferred. We
compare to semi-analytical models, and find that the lack of evolution in M* is
consistent with models where the impact of dust attenuation on the bright-end
of the luminosity function decreases at higher redshift. We measure the
evolution of the cosmic star-formation rate density, correcting for dust
attenuation, and find that it declines as (1+z)^(-4.3 +/- 0.5) at z>4,
consistent with observations at z>9. Our observations are consistent with a
reionization history that starts at z>10, completes at z>6, and reaches a
midpoint (x_HII = 0.5) at 6.7<z<9.4. Finally, our observations predict that the
abundance of bright z=9 galaxies is likely higher than previous constraints,
though consistent with recent estimates of bright z~10 galaxies. [abridged]Comment: Re-submitted to the Astrophysical Journal after first referee's
report. 34 pages, 21 figures, 7 tables. The source file includes a machine
readable table of our full galaxy sampl
A comprehensive study of H emitters at 0.62 in the DAWN survey: the need for deep and wide regions
We present new estimates of the luminosity function (LF) and star formation
rate density (SFRD) for an H selected sample at from the
Deep And Wide Narrow-band (DAWN) survey. Our results are based on a new
H sample in the extended COSMOS region (compared to Coughlin et al.
2018) with the inclusion of flanking fields, resulting in a total area coverage
of 1.5 deg. A total of 241 H emitters were selected based on
robust selection criteria using spectro-photometric redshifts and broadband
color-color classification. We explore the effect of different dust correction
prescriptions by calculating the LF and SFRD using a constant dust extinction
correction, A{} mag, a luminosity-dependent correction,
and a stellar-mass dependent correction. The resulting H LFs are well
fitted using Schechter functions with best-fit parameters: L erg
s, Mpc, for constant dust
correction, L erg s, Mpc,
for luminosity-dependent dust correction, and L
erg s, Mpc, , for stellar
mass-dependent dust correction. The deep and wide nature of the DAWN survey
effectively samples H emitters over a wide range of luminosities,
thereby providing better constraints on both the faint and bright end of the
LF. Also, the SFRD estimates
MyrMpc (constant dust correction),
MyrMpc
(luminosity-dependent dust correction), and
MyrMpc (stellar mass-dependent dust correction) are in
good agreement with the evolution of SFRD across redshifts () seen
from previous H surveys.Comment: 16 pages, 8 figures, Accepted for publication in Ap
H alpha Emitting Galaxies at z similar to 0.6 in the Deep And Wide Narrow-band Survey
Abstract
We present new measurements of the Hα luminosity function (LF) and star formation rate (SFR) volume density for galaxies at z?~?0.62 in the COSMOS field. Our results are part of the Deep And Wide Narrow-band Survey (DAWN), a unique infrared imaging program with large areal coverage (~1.1 deg2 over five fields) and sensitivity (
at 5σ). The present sample, based on a single DAWN field, contains 116 Hα emission-line candidates at z?~?0.62, 25% of which have spectroscopic confirmations. These candidates have been selected through the comparison of narrow and broad-band images in the infrared and through matching with existing catalogs in the COSMOS field. The dust-corrected LF is well described by a Schechter function with
erg s?1,
Mpc?3,
erg s?1 Mpc?3, and α?=??1.75?±?0.09. From this LF, we calculate a SFR density of ρSFR?=?10?1.37?±?0.08 M⊙ yr?1 Mpc?3. We expect an additional cosmic variance uncertainty of ~20%. Both the faint end slope and luminosity density that we derive are consistent with prior results at similar redshifts, with reduced uncertainties. We also present an analysis of these Hα emitters’ sizes, which shows a direct correlation between the galaxies’ sizes and their Hα emission
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The Relation Between Star Formation Rate and Stellar Mass For Galaxies at 3.5 \u3c z \u3c 6.5 in CANDELS
Halpha Emitting Galaxies at Z ~ 0.6 in the Deep and Wide Narrow-Band Survey
We present new measurements of the H luminosity function (LF) and star formation rate (SFR) volume density for galaxies at z0.62 in the COSMOS field. Our results are part of the Deep And Wide Narrow-band Survey (DAWN), a unique infrared imaging program with large areal coverage (1.1 deg2 over five fields) and sensitivity (9.9 x 10(exp -18) erg cm(exp -2) s(exp -1) at 5). The present sample, based on a single DAWN field, contains 116 H emission line candidates at z0.62, 25% of which have spectroscopic confirmations. These candidates have been selected through the comparison of narrow and broad-band images in the infrared and through matching with existing catalogs in the COSMOS field. The dust-corrected LF is well described by a Schechter function with L* = 10 (exp 42.64 +/- 0.92) erg s (exp 1), Phi* = 10 (exp -3.320.93)Mpc(exp 3), L*Phi* = L 10(exp 39.40) 0.15 erg s(exp 1)Mpc(exp 3), and =1.75+/-0.09. From this LF, we calculate a SFR density of SFR=10(exp 1.37+/-0.08)solar mass yr(exp 1)Mpc(exp 3). We expect an additional cosmic variance uncertainty of 20%. Both the faint end slope and luminosity density that we derive are consistent with prior results at similar redshifts, with reduced uncertainties. We also present an analysis of these H emitters' sizes, which shows a direct correlation between the galaxies' sizes and their H emission
Galaxy stellar mass functions from ZFOURGE/CANDELS: an excess of low-mass galaxies since z=2 and the rapid buildup of quiescent galaxies
Using observations from the FourStar Galaxy Evolution Survey (ZFORUGE), we obtain the deepest measurements to date of the galaxy stellar mass function at 0.5<z<2.5. ZFORUGE provides well-constrained photometric redshifts made possible through deep medium-bandwidth imaging at 1-