66 research outputs found
Measurements of the spectral energy distribution of the cosmic infrared background
The extragalactic background light (EBL) is the relic emission of all
processes of structure formation in the Universe. About half of this
background, called the Cosmic Infrared Background (CIB) is emitted in the
8-1000 microns range, and peaks around 150 microns. It is due to the dust
reemission from star formation processes and AGN emission. The CIB spectral
energy distribution (SED) constraints the models of star formation in the
Universe. It is also useful to compute the opacity of the Universe to the TeV
photons.
We present the different types of measurements of the CIB and discuss their
strengths and weaknesses.
1. The absolute SED was measured by COBE, and by other experiments. These
measurements are limited by the accuracy of the component separation, i.e. the
foreground subtraction.
2. Robust lower limits are determined from the extragalactic number counts of
infrared galaxies. These lower limits are very stringent up to 100 microns. At
larger wavelengths, the rather low angular resolution of the instruments limits
strongly the depth of the number counts. The "stacking" method determines the
flux emitted at a given wavelength by a population detected at another
wavelength, and provides stringent lower limits in the sub-mm range. It is
complementary with other methods based on the statistical analysis of the map
properties like the P(D) analysis.
3. Finally, upper limits can be derived from the high energy spectra of
extragalactic sources. These upper limits give currently good constraints in
the near- and mid-IR.
Progress have been amazing since the CIB discovery about 15 years ago: the
SED is much better known, and most of it can be accounted for by galaxies
(directly or indirectly). Prospects are also exciting, with fluctuation
analysis with Planck&Herschel, and forthcoming missions.Comment: 9 pages, 1 figure, 1 table, proceedings of invited talk at CRF2010,
DESY Hamburg, Nov 9-12 201
Metal enrichment in a semi-analytical model, fundamental scaling relations, and the case of Milky Way galaxies
Gas flows play a fundamental role in galaxy formation and evolution,
providing the fuel for the star formation process. These mechanisms leave an
imprint in the amount of heavy elements. Thus, the analysis of this metallicity
signature provides additional constraint on the galaxy formation scenario. We
aim to discriminate between four different galaxy formation models based on two
accretion scenarios and two different star formation recipes. We address the
impact of a bimodal accretion scenario and a strongly regulated star formation
recipe. We present a new extension of the eGalICS model, which allows us to
track the metal enrichment process. Our new chemodynamical model is applicable
for situations ranging from metal-free primordial accretion to very enriched
interstellar gas contents. We use this new tool to predict the metallicity
evolution of both the stellar populations and gas phase. We also address the
evolution of the gas metallicity with the star formation rate (SFR). We then
focus on a sub-sample of Milky Way-like galaxies. We compare both the cosmic
stellar mass assembly and the metal enrichment process of such galaxies with
observations and detailed chemical evolution models. Our models, based on a
strong star formation regulation, allow us to reproduce well the stellar mass
to gas-phase metallicity relation observed in the local universe. However, we
observe a systematic shift towards high masses. Our $Mstar-Zg-SFR relation is
in good agreement with recent measurements: our best model predicts a clear
dependence with the SFR. Both SFR and metal enrichment histories of our Milky
Way-like galaxies are consistent with observational measurements and detailed
chemical evolution models. We finally show that Milky Way progenitors start
their evolution below the observed main sequence and progressively reach this
observed relation at z = 0.Comment: 22 pages, 11 figure
The influence of wavelength, flux, and lensing selection effects on the redshift distribution of dusty, star-forming galaxies
We interpret the large variety of redshift distributions of galaxies found by far-infrared and (sub-)millimeter deep surveys depending on their depth and wavelength using the Bethermin et al. (2012) phenomenological model of galaxy evolution. This model reproduces without any new parameter tuning the observed redshift distributions from 100 μm to 1.4 mm, and especially the increase of the median redshift with survey wavelength. This median redshift varies also significantly with the depth of the surveys, and deeper surveys do necessarily not probe higher redshifts. Paradoxically, at fixed wavelength and flux limit, the lensed sources are not always at higher redshift. We found that the higher redshift of 1.4 mm-selected south pole telescope (SPT) sources compared to other SMG surveys is not only caused by the lensing selection, but also by the longer wavelength. This SPT sample is expected to be dominated by a population of lensed main-sequence galaxies and a minor contribution (∼10%) of unlensed extreme starbursts
The early early type: discovery of a passive galaxy at z=3
We present the discovery of a massive, quiescent galaxy at z=2.99. We have
obtained a HST/WFC3 spectrum of this object and measured its redshift from the
detection of a deep 4000A break consistent with an old population and a high
metallicity. By stellar population modeling of both its grism spectrum and
broad-band photometry, we derive an age of ~0.7 Gyr, implying a formation
redshift of z>4, and a mass >10^11 Msun. Although this passive galaxy is the
most distant confirmed so far, we find that it is slightly less compact than
other z>2 early-types of similar mass, being overall more analogous to those
z~1.6 field early-type galaxies. The discovery of this object shows that
early-type galaxies are detectable to at least z=3 and suggests that the
diversity of structural properties found in z=1.4-2 ellipticals to earlier
epochs could have its origin in a variety of formation histories among their
progenitors.Comment: 6 pages, 4 figures, 1 table. Accepted for publication in The
Astrophysical Journal Letter
The redshift evolution of the distribution of star formation among dark matter halos as seen in the infrared
Recent studies have revealed a strong correlation between the star formation rate (SFR) and stellar mass of the majority of star-forming galaxies, the so-called star-forming main sequence. An empirical modeling approach (the 2-SFM framework) that distinguishes between the main sequence and rarer starburst galaxies is capable of reproducing most statistical properties of infrared galaxies, such as number counts, luminosity functions, and redshift distributions. In this paper, we extend this approach by establishing a connection between stellar mass and halo mass with the technique of abundance matching. Based on a few simple assumptions and a physically motivated formalism, our model successfully predicts the (cross-)power spectra of the cosmic infrared background (CIB), the cross-correlation between CIB and cosmic microwave background (CMB) lensing, and the correlation functions of bright, resolved infrared galaxies measured by Herschel, Planck, ACT, and SPT. We use this model to infer the redshift distribution of CIB-anisotropies and of the CIB × CMB lensing signal, as well as the level of correlation between CIB-anisotropies at different wavelengths. We study the link between dark matter halos and star-forming galaxies in the framework of our model. We predict that more than 90% of cosmic star formation activity occurs in halos with masses between 1011.5 and 10^(13.5) M⊙. If taking subsequent mass growth of halos into account, this implies that the majority of stars were initially (at z > 3) formed in the progenitors of clusters (M_h(z = 0) > 10^(13.5) M⊙), then in groups (10^(12.5) < M_h(z = 0) < 10^(13.5) M⊙) at 0.5 < z < 3, and finally in Milky-Way-like halos (10^(11.5) < M_h(z = 0) < 10^(12.5) M⊙) at z < 0.5. At all redshifts, the dominant contribution to the SFR density stems from halos of mass ~10¹² M⊙, in which the instantaneous star formation efficiency – defined here as the ratio between SFR and baryonic accretion rate – is maximal (~70%). The strong redshift-evolution of SFR in the galaxies that dominate the CIB is thus plausibly driven by increased accretion from the cosmic web onto halos of this characteristic mass scale. Material (effective spectral energy distributions, differential emissivities of halos, relations between M_h and SFR) associated to this model is available at http://irfu.cea.fr/Sap/Phocea/Page/index.php?id=537
The redshift evolution of the distribution of star formation among dark matter halos as seen in the infrared
Recent studies revealed a strong correlation between the star formation rate (SFR) and stellar mass of star-forming galaxies, the so-called star-forming main sequence. An empirical modeling approach (2-SFM) which distinguishes between the main sequence and rarer starburst galaxies is capable of reproducing most statistical properties of infrared galaxies. In this paper, we extend this approach by establishing a connection between stellar mass and halo mass with the technique of abundance matching. Based on a few, simple assumptions and a physically motivated formalism, our model successfully predicts the (cross-)power spectra of the cosmic infrared background (CIB), the cross-correlation between CIB and cosmic microwave background (CMB) lensing, and the correlation functions of bright, resolved infrared galaxies measured by Herschel, Planck, ACT and SPT. We use this model to infer the redshift distribution these observables, as well as the level of correlation between CIB-anisotropies at different wavelengths. We also predict that more than 90% of cosmic star formation activity occurs in halos with masses between 10^11.5 and 10^13.5 Msun. Taking into account subsequent mass growth of halos, this implies that the majority of stars were initially (at z>3) formed in the progenitors of clusters, then in groups at 0.5<z<3 and finally in Milky-Way-like halos at z<0.5. At all redshifts, the dominant contribution to the star formation rate density stems from halos of mass ~10^12 Msun, in which the instantaneous star formation efficiency is maximal (~70%). The strong redshift-evolution of SFR in the galaxies that dominate the CIB is thus plausibly driven by increased accretion from the cosmic web onto halos of this characteristic mass scale
Separation of dust emission from the Cosmic Infrared Background in Herschel observations with Wavelet Phase Harmonics
The low brightness dust emission at high Galactic latitude is of interest to
study the interplay between physical processes in shaping the structure of the
interstellar medium (ISM), as well as to statistically characterize dust
emission as a foreground to the Cosmic Microwave Background (CMB). Progress in
this avenue of research have been hampered by the difficulty of separating the
dust emission from the Cosmic Infrared Background (CIB). We demonstrate that
dust and CIB may be effectively separated based on their different structure on
the sky and use the separation to characterize the structure of diffuse dust
emission on angular scales where CIB is a significant component in terms of
power. We use scattering transform statistics, the Wavelet Phase Harmonics
(WPH), to perform a statistical component separation using Herschel SPIRE
observations. This component separation is done only from observational data
using non-Gaussian properties as a lever arm, and is done at a single 250
microns frequency. This method, that we validate on mock data, gives us access
to non-Gaussian statistics of the interstellar dust and an output dust map
essentially free from CIB contamination. Our statistical modelling
characterizes the non-Gaussian structure of the diffuse ISM down to the
smallest scales observed by Herschel. We recover the power-law shape of the
dust power spectrum up to a wavenumber of 2 arcmin where the dust signal
represents 2 percent of the total power. The output dust map reveals coherent
structures at the smallest scales which were hidden by the CIB anisotropies. It
opens new observational perspectives on the formation of structure in the
diffuse ISM which we discuss with reference to past work. We have succeeded to
perform a statistical separation from observational data only at a single
frequency by using non-Gaussian statistics.Comment: Accepted in A&A on October 23, 202
The Herschel view of the dominant mode of galaxy growth from z=4 to the present day
We present an analysis of the deepest Herschel images in four major extragalactic fields GOODS-North, GOODS-South, UDS and COSMOS obtained within the GOODS-Herschel and CANDELS-Herschel key programs. The picture provided by 10497 individual far-infrared detections is supplemented by the stacking analysis of a mass-complete sample of 62361 star-forming galaxies from the CANDELS-HST H band-selected catalogs and from two deep ground-based Ks band-selected catalogs in the GOODS-North and the COSMOS-wide fields, in order to obtain one of the most accurate and unbiased understanding to date of the stellar mass growth over the cosmic history. We show, for the first time, that stacking also provides a powerful tool to determine the dispersion of a physical correlation and describe our method called "scatter stacking" that may be easily generalized to other experiments. We demonstrate that galaxies of all masses from z=4 to 0 follow a universal scaling law, the so-called main sequence of star-forming galaxies. We find a universal close-to-linear slope of the logSFR-logM* relation with evidence for a flattening of the main sequence at high masses (log(M*/Msun) > 10.5) that becomes less prominent with increasing redshift and almost vanishes by z~2. This flattening may be due to the parallel stellar growth of quiescent bulges in star-forming galaxies. Within the main sequence, we measure a non varying SFR dispersion of 0.3 dex. The specific SFR (sSFR=SFR/M*) of star-forming galaxies is found to continuously increase from z=0 to 4. Finally we discuss the implications of our findings on the cosmic SFR history and show that more than 2/3 of present-day stars must have formed in a regime dominated by the main sequence mode. As a consequence we conclude that, although omnipresent in the distant Universe, galaxy mergers had little impact in shaping the global star formation history over the last 12.5 Gyr
The impact of clustering and angular resolution on far-infrared and millimeter continuum observations
Follow-up observations at high-angular resolution of bright submillimeter galaxies selected from deep extragalactic surveys have shown that the single-dish sources are comprised of a blend of several galaxies. Consequently, number counts derived from low- and high-angular-resolution observations are in tension. This demonstrates the importance of resolution effects at these wavelengths and the need for realistic simulations to explore them. We built a new 2 deg simulation of the extragalactic sky from the far-infrared to the submillimeter. It is based on an updated version of the 2SFM (two star-formation modes) galaxy evolution model. Using global galaxy properties generated by this model, we used an abundance-matching technique to populate a dark-matter lightcone and thus simulate the clustering. We produced maps from this simulation and extracted the sources, and we show that the limited angular resolution of single-dish instruments has a strong impact on (sub)millimeter continuum observations. Taking into account these resolution effects, we are reproducing a large set of observables, as number counts and their evolution with redshift and cosmic infrared background power spectra. Our simulation consistently describes the number counts from single-dish telescopes and interferometers. In particular, at 350 and 500 \uce\ubcm, we find that the number counts measured by Herschel between 5 and 50 mJy are biased towards high values by a factor 2, and that the redshift distributions are biased towards low redshifts. We also show that the clustering has an important impact on the Herschel pixel histogram used to derive number counts from P(D) analysis. We find that the brightest galaxy in the beam of a 500 \uce\ubcm Herschel source contributes on average to only 60% of the Herschel flux density, but that this number will rise to 95% for future millimeter surveys on 30 m-class telescopes (e.g., NIKA2 at IRAM). Finally, we show that the large number density of red Herschel sources found in observations but not in models might be an observational artifact caused by the combination of noise, resolution effects, and the steepness of color- and flux density distributions. Our simulation, called Simulated Infrared Dusty Extragalactic Sky (SIDES), is publicly available
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