441 research outputs found
CO lines in high redshift galaxies: perspective for future mm instruments
Nearly 10 high redshift (z>2) starburst galaxies have recently been detected
in the CO lines, revealing the early presence in the universe of objects with
large amounts of already-enriched molecular gas. The latter has sufficient
density to be excited in the high-level rotational CO lines, which yield more
flux, making easier high-redshift detections; however the effect is not as
strong as for the sub-millimeter and far-infrared dust continuum emission. With
the help of simple galaxy models, based on these first detections, we estimate
the flux in all CO lines expected for such starbursting objects at various
redshifts. We discuss the detection perspectives with the future millimeter
instruments.Comment: 11 pages, 11 figures, accepted in A &
Mass - concentration relation and weak lensing peak counts
The statistics of peaks in weak lensing convergence maps is a promising tool
to investigate both the properties of dark matter haloes and constrain the
cosmological parameters. We study how the number of detectable peaks and its
scaling with redshift depend upon the cluster dark matter halo profiles and use
peak statistics to constrain the parameters of the mass - concentration (MC)
relation. We investigate which constraints the Euclid mission can set on the MC
coefficients also taking into account degeneracies with the cosmological
parameters. To this end, we first estimate the number of peaks and its redshift
distribution for different MC relations. We find that the steeper the mass
dependence and the larger the normalisation, the higher is the number of
detectable clusters, with the total number of peaks changing up to
depending on the MC relation. We then perform a Fisher matrix forecast of the
errors on the MC relation parameters as well as cosmological parameters. We
find that peak number counts detected by Euclid can determine the normalization
, the mass and redshift slopes and intrinsic scatter
of the MC relation to an unprecedented accuracy being
, , ,
if all cosmological parameters are assumed to
be known. Should we relax this severe assumption, constraints are degraded, but
remarkably good results can be restored setting only some of the parameters or
combining peak counts with Planck data. This precision can give insight on
competing scenarios of structure formation and evolution and on the role of
baryons in cluster assembling. Alternatively, for a fixed MC relation, future
peaks counts can perform as well as current BAO and SNeIa when combined with
Planck.Comment: 14 pages, 8 figures, accepted for publication on Astronomy &
Astrophysic
Searching for galaxy clusters using the aperture mass statistics in 50 VLT fields
Application of the aperture mass (Map-) statistics provides a weak lensing
method for the detection of cluster-sized dark matter halos. We present a new
aperture filter function and maximise the effectiveness of the Map-statistics
to detect cluster-sized halos using analytical models. We then use weak lensing
mock catalogues generated from ray-tracing through N-body simulations, to
analyse the effect of image treatment on the expected number density of halos.
Using the Map-statistics, the aperture radius is typically several arcminutes,
hence the aperture often lies partly outside a data field, consequently the
signal-to-noise ratio of a halo detection decreases. We study these border
effects analytically and by using mock catalogues. We find that the expected
number density of halos decreases by a factor of two if the size of a field is
comparable to the diameter of the aperture used. We finally report on the
results of a weak lensing cluster search applying the Map-statistics to 50
randomly selected fields which were observed with FORS1 at the VLT. Altogether
the 50 VLT fields cover an area of 0.64 square degrees. The I-band images were
taken under excellent seeing conditions (average seeing 0.6 arcsec.) which
results in a high number density of galaxies used for the weak lensing analysis
(26/sq.arcmin). In five of the VLT fields, we detect a significant Map-signal
which coincides with an overdensity of the light distribution. These detections
are thus excellent candidates for shear-selected clusters.Comment: 23 pages, 5 tables, 24 figures, published in A&A, Sect. 3.5 and 7 are
changed or altered; Fig. 11 is change
The power spectrum of systematics in cosmic shear tomography and the bias on cosmological parameters
Cosmic shear tomography has emerged as one of the most promising tools to
both investigate the nature of dark energy and discriminate between General
Relativity and modified gravity theories. In order to successfully achieve
these goals, systematics in shear measurements have to be taken into account;
their impact on the weak lensing power spectrum has to be carefully
investigated in order to estimate the bias induced on the inferred cosmological
parameters. To this end, we develop here an efficient tool to compute the power
spectrum of systematics by propagating, in a realistic way, shear measurement,
source properties and survey setup uncertainties. Starting from analytical
results for unweighted moments and general assumptions on the relation between
measured and actual shear, we derive analytical expressions for the
multiplicative and additive bias, showing how these terms depend not only on
the shape measurement errors, but also on the properties of the source galaxies
(namely, size, magnitude and spectral energy distribution). We are then able to
compute the amplitude of the systematics power spectrum and its scaling with
redshift, while we propose a multigaussian expansion to model in a
non-parametric way its angular scale dependence. Our method allows to
self-consistently propagate the systematics uncertainties to the finally
observed shear power spectrum, thus allowing us to quantify the departures from
the actual spectrum. We show that even a modest level of systematics can induce
non-negligible deviations, thus leading to a significant bias on the recovered
cosmological parameters.Comment: 19 pages, 5 tables, 4 figure
Calibration of colour gradient bias in shear measurement using HST/CANDELS data
Accurate shape measurements are essential to infer cosmological parameters from large area weak gravitational lensing studies. The compact diffraction-limited point-spread function (PSF) in space-based observations is greatly beneficial, but its chromaticity for a broad band observation can lead to new subtle effects that could hitherto be ignored: the PSF of a galaxy is no longer uniquely defined and spatial variations in the colours of galaxies result in biases in the inferred lensing signal. Taking Euclid as a reference, we show that this colourgradient bias (CG bias) can be quantified with high accuracy using available multi-colour Hubble Space Telescope (HST) data. In particular we study how noise in the HST observations might impact such measurements and find this to be negligible. We determine the CG bias using HST observations in the F606W and F814W filters and observe a correlation with the colour, in line with expectations, whereas the dependence with redshift is weak. The biases for individual galaxies are generally well below 1%, which may be reduced further using morphological information from the Euclid data. Our results demonstrate that CG bias should not be ignored, but it is possible to determine its amplitude with sufficient precision, so that it will not significantly bias the weak lensing measurements using Euclid data
Cosmic shear surveys
Gravitational weak shear produced by large-scale structures of the universe
induces a correlated ellipticity distribution of distant galaxies. The
amplitude and evolution with angular scale of the signal depend on cosmological
models and can be inverted in order to constrain the power spectrum and the
cosmological parameters. We present our recent analysis of 50 uncorrelated VLT
fields and the very first constrains on () and the nature of
primordial fluctuations based on the join analysis of present-day cosmic shear
surveys.Comment: Latex, 7 pages. To appear in the ESO Proceedings ``Deep Fields'',
Garching Oct 9-12, 200
Jointly fitting weak lensing, x-ray, and Sunyaev-Zel'dovich data to constrain scalar-tensor theories with clusters of galaxies
Degenerate higher-order scalar-tensor (DHOST) theories are considered the most general class of scalar-tensor theories with an additional scalar field. DHOST theories modify the laws of gravity even at galaxy clusters scale hence affecting the weak lensing, x-ray, and Sunyaev-Zel'dovich observables. We derive the theoretical expression for the lensing convergence Îș and the pressure profile P of clusters in the framework of DHOST theories and quantify how much they deviate from their general relativity counterparts. We argue that combined measurements of Îș, P, and of the electron number density ne can constrain both the cluster parameters and some effective parameters of the DHOST theory. We carry on a Fisher matrix forecasts analysis to investigate whether this is indeed the case considering different scenarios for the spatial resolution and errors on the measured quantities
Molecular signals from primordial clouds at high redshift
The possibility to detect cosmological signals from the post-recombination
Universe is one of the main aims of modern cosmology. In a previous paper we
emphasized the role that elastic resonant scattering through LiH molecules can
have in dumping primary CBR anisotropies and raising secondary signals. Here we
extend our analysis to all the evolutionary stages of a primordial cloud,
starting with the linear phase, through the turn-around and to the non linear
collapse. We have done calculations for proto-clouds in a CDM scenario and,
more generally, for a set of clouds with various masses and various turn-around
redshifts, in this case without referring to any particular structure formation
scenario. We found that the first phase of collapse, for
is the best one for simultaneous detection of
the first two LiH rotational lines. The observational frequency falls between
30 and 250 GHz and the line width is between
and . As far as we know this is the most favourable process to detect
primordial clouds before they start star formation processes.Comment: 26 pages, uuencoded compressed postscript, 7 figures included.
Accepted for publication in Ap.
A 380 GHz SIS receiver using Nb/AlO(x)/Nb junctions for a radioastronomical balloon-borne experiment: PRONAOS
The superheterodyne detection technique used for the spectrometer instrument of the PRONAOS project will provide a very high spectral resolution (delta nu/nu = 10(exp -6)). The most critical components are those located at the front-end of the receiver: their contribution dominates the total noise of the receiver. Therefore, it is important to perform accurate studies for specific components, such as mixers and multipliers working in the submillimeter wave range. Difficulties in generating enough local oscillator (LO) power at high frequencies make SIS mixers very desirable for operation above 300 GHz. The low LO power requirements and the low noise temperature of these mixers are the primary reason for building an SIS receiver. This paper reports the successful fabrication of small (less than or equal to 1 sq micron) Nb/Al-O(x)/Nb junctions and arrays with excellent I-V characteristics and very good reliability, resulting in a low noise receiver performance measured in the 368/380 GHz frequency range
- âŠ