360 research outputs found
The Reionization of Carbon
Observations suggest that CII was more abundant than CIV in the intergalactic
medium towards the end of the hydrogen reionization epoch. This transition
provides a unique opportunity to study the enrichment history of intergalactic
gas and the growth of the ionizing background (UVB) at early times. We study
how carbon absorption evolves from z=10-5 using a cosmological hydrodynamic
simulation that includes a self-consistent multifrequency UVB as well as a
well-constrained model for galactic outflows to disperse metals. Our predicted
UVB is within 2-4 times that of Haardt & Madau (2012), which is fair agreement
given the uncertainties. Nonetheless, we use a calibration in post-processing
to account for Lyman-alpha forest measurements while preserving the predicted
spectral slope and inhomogeneity. The UVB fluctuates spatially in such a way
that it always exceeds the volume average in regions where metals are found.
This implies both that a spatially-uniform UVB is a poor approximation and that
metal absorption is not sensitive to the epoch when HII regions overlap
globally even at column densites of 10^{12} cm^{-2}. We find, consistent with
observations, that the CII mass fraction drops to low redshift while CIV rises
owing the combined effects of a growing UVB and continued addition of carbon in
low-density regions. This is mimicked in absorption statistics, which broadly
agree with observations at z=6-3 while predicting that the absorber column
density distributions rise steeply to the lowest observable columns. Our model
reproduces the large observed scatter in the number of low-ionization absorbers
per sightline, implying that the scatter does not indicate a partially-neutral
Universe at z=6.Comment: 16 pages, 14 figures, accepted to MNRA
The impact of nebular emission on the broadband fluxes of high-redshift galaxies
A substantial fraction of the light emitted from young or star-forming
galaxies at ultraviolet to near-infrared wavelengths comes from the ionized
interstellar medium in the form of emission lines and a nebular continuum. At
high redshifts, star formation rates are on average higher and stellar
populations younger than in the local Universe. Both of these effects act to
boost the impact of nebular emission on the overall spectrum of galaxies. Even
so, the broadband fluxes and colours of high-redshift galaxies are routinely
analyzed under the assumption that the light observed originates directly from
stars. Here, we assess the impact of nebular emission on broadband fluxes in
Johnson/Cousins BVRIJHK, Sloan Digital Sky Survey griz and Spitzer IRAC/MIPS
filters as a function of observed redshift (up to z=15) for galaxies with
different star formation histories. We find that nebular emission may account
for a non-negligible fraction of the light received from high-redshift
galaxies. The ages and masses inferred for such objects through the use of
spectral evolutionary models that omit the nebular contribution are therefore
likely to contain systematic errors. We argue that a careful treatment of the
nebular component will be essential for the interpretation of the rest-frame
ultraviolet-to-infrared properties of the first galaxies formed, like the ones
expected to be detected with the James Webb Space Telescope.Comment: 5 pages, 3 figures, accepted for publication in ApJ
First detection of Lyman continuum escape from a local starburst galaxy
The dominating reionization source in the young universe has yet to be
identified. Possible candidates include metal poor starburst dwarf galaxies of
which the Blue Compact Galaxy Haro 11 may represent a local counterpart. Using
the Far Ultraviolet Spectroscopic Explorer (FUSE) we obtained spectra of Haro
11 to search for leaking ionizing radiation. A weak signal shortwards of the
Lyman break is identified as Lyman continuum (LyC) emission escaping from the
ongoing starburst. From profile fitting to weak metal lines we derive column
densities of the low ionization species. Adopting a metallicity typical of the
H II regions of Haro 11, the corresponding H I column density is optically
thick in the LyC. Therefore most of the LyC photons must escape through
transparent holes in the interstellar medium. Using spectral evolutionary
models we constrain the escape fraction of the produced LyC photons to between
4 and 10%, assuming a normal Salpeter IMF. We argue that in a hierarchical
galaxy formation scenario, this allows for a substantial contribution to cosmic
reionization by starburst dwarf galaxies at high redshifts.Comment: Accepted for publication in Astronomy and Astrophysic
A Link to the Past: Using Markov Chain Monte Carlo Fitting to Constrain Fundamental Parameters of High-Redshift Galaxies
We have a developed a new method for fitting spectral energy distributions
(SEDs) to identify and constrain the physical properties of high-redshift (4 <
z < 8) galaxies. Our approach uses an implementation of Bayesian based Markov
Chain Monte Carlo (PiMC^2) that allows us to compare observations to
arbitrarily complex models and to compute 95% credible intervals that provide
robust constraints for the model parameters. The work is presented in 2
sections. In the first, we test PiMC^2 using simulated SEDs to not only confirm
the recovery of the known inputs but to assess the limitations of the method
and identify potential hazards of SED fitting when applied specifically to high
redshift (z>4) galaxies. Our tests reveal five critical results: 1) the ability
to confidently constrain metallicity, population ages, and Av all require
photometric accuracy better than what is currently achievable (i.e. less than a
few percent); 2) the ability to confidently constrain stellar masses (within a
factor of two) can be achieved without the need for high-precision photometry;
3) the addition of IRAC photometry does not guarantee that tighter constraints
of the stellar masses and ages can be defined; 4) different assumptions about
the star formation history can lead to significant biases in mass and age
estimates; and 5) we are able to constrain stellar age and Av of objects that
are both young and relatively dust free. In the second part of the paper we
apply PiMC^2 to 17 4<z<8 objects, including the GRAPES Ly alpha sample (4<z<6),
supplemented by HST/WFC3 near-IR observations, and several broad band selected
z>6 galaxies. Using PiMC^2, we are able to constrain the stellar mass of these
objects and in some cases their stellar age and find no evidence that any of
these sources formed at a redshift much larger than z_f=8, a time when the
Universe was ~ 0.6 Gyr old.Comment: Submitted to ApJ (Full abstract, 47 pages, 17 figures, 7 tables
Prospects for CDM sub-halo detection using high angular resolution observations
In the CDM scenario, dark matter halos are assembled hierarchically from
smaller subunits. A long-standing problem with this picture is that the number
of sub-halos predicted by CDM simulations is orders of magnitudes higher than
the known number of satellite galaxies in the vicinity of the Milky Way. A
plausible way out of this problem could be that the majority of these sub-halos
somehow have so far evaded detection. If such "dark galaxies" do indeed exist,
gravitational lensing may offer one of the most promising ways to detect them.
Dark matter sub-halos in the 1e6 - 1e10 solar mass range should cause strong
gravitational lensing on (sub)milliarcsecond scales. We study the feasibility
of a strong lensing detection of dark sub-halos by deriving the image
separations expected for density profiles favoured by recent simulations and
comparing these to the angular resolution of both existing and upcoming
observational facilities. We find that there is a reasonable probability to
detect sub-halo lensing effects in high resolution observations at radio
wavelengths, such as produced by the upcoming VSOP-2 satellite, and thereby
test the existence of dark galaxies.Comment: 9 pages, 5 figures, Proceedings for "The Universe under the
Microscope" (AHAR 2008), held in Bad Honnef (Germany) in April 2008, to be
published in Journal of Physics: Conference Series by Institute of Physics
Publishing, R. Schoedel, A. Eckart, S. Pfalzner, and E. Ros (eds.
A Link to the Past: Using Markov Chain Monte Carlo Fitting to Constrain Fundamental Parameters of High-Redshift Galaxies
We have a developed a new method for fitting spectral energy distributions
(SEDs) to identify and constrain the physical properties of high-redshift (4 <
z < 8) galaxies. Our approach uses an implementation of Bayesian based Markov
Chain Monte Carlo (PiMC^2) that allows us to compare observations to
arbitrarily complex models and to compute 95% credible intervals that provide
robust constraints for the model parameters. The work is presented in 2
sections. In the first, we test PiMC^2 using simulated SEDs to not only confirm
the recovery of the known inputs but to assess the limitations of the method
and identify potential hazards of SED fitting when applied specifically to high
redshift (z>4) galaxies. Our tests reveal five critical results: 1) the ability
to confidently constrain metallicity, population ages, and Av all require
photometric accuracy better than what is currently achievable (i.e. less than a
few percent); 2) the ability to confidently constrain stellar masses (within a
factor of two) can be achieved without the need for high-precision photometry;
3) the addition of IRAC photometry does not guarantee that tighter constraints
of the stellar masses and ages can be defined; 4) different assumptions about
the star formation history can lead to significant biases in mass and age
estimates; and 5) we are able to constrain stellar age and Av of objects that
are both young and relatively dust free. In the second part of the paper we
apply PiMC^2 to 17 4<z<8 objects, including the GRAPES Ly alpha sample (4<z<6),
supplemented by HST/WFC3 near-IR observations, and several broad band selected
z>6 galaxies. Using PiMC^2, we are able to constrain the stellar mass of these
objects and in some cases their stellar age and find no evidence that any of
these sources formed at a redshift much larger than z_f=8, a time when the
Universe was ~ 0.6 Gyr old.Comment: Submitted to ApJ (Full abstract, 47 pages, 17 figures, 7 tables
The properties of SN Ib/c locations
Aims: To gain better insight on the physics of stripped-envelope
core-collapse supernovae through studying their environments. Methods: We
obtained low-resolution optical spectroscopy with the New Technology Telescope
(+ EFOSC2) at the locations of 20 Type Ib/c supernovae. We measure the flux of
emission lines in the stellar-continuum-subtracted spectra from which local
metallicities are computed. For the supernova regions we estimate both the mean
stellar age, interpreting the stellar absorption with population synthesis
models, and the age of the youngest stellar populations using the H-alpha
equivalent width as an age indicator. These estimates are compared with the
lifetimes of single massive stars. Results: Based on our sample, we detect a
tentative indication that Type Ic supernovae might explode in environments that
are more metal-rich than those of Type Ib supernovae (average difference of
0.08 dex), but this is not a statistically significant result. The lower limits
placed on the ages of the supernova birthplaces are overall young, although
there are several cases where these appear older than what is expected for the
evolution of single stars more massive than 25-30 M_{sun}. This is only true,
however, assuming that the supernova progenitors were born during an
instantaneous (not continuous) episode of star formation. Conclusions: These
results do not conclusively favor any of the two evolutionary paths (single or
binary) leading to stripped supernovae. We do note a fraction of events for
which binary evolution is more likely, due to their associated age limits. The
fact, however, that the supernova environments contain areas of recent (< 15
Myr) star formation and that the environmental metallicities are, at least, not
against the single evolutionary scenario, suggest that this channel is also
broadly consistent with the observations.Comment: Matches published version (after proofs
21-cm cosmology
Imaging the Universe during the first hundreds of millions of years remains
one of the exciting challenges facing modern cosmology. Observations of the
redshifted 21 cm line of atomic hydrogen offer the potential of opening a new
window into this epoch. This would transform our understanding of the formation
of the first stars and galaxies and of the thermal history of the Universe. A
new generation of radio telescopes is being constructed for this purpose with
the first results starting to trickle in. In this review, we detail the physics
that governs the 21 cm signal and describe what might be learnt from upcoming
observations. We also generalize our discussion to intensity mapping of other
atomic and molecular lines.Comment: 64 pages, 20 figures, submitted to Reports on Progress in Physics,
comments welcom
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