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The ALMA Spectroscopic Survey in the HUDF: A model to explain observed 1.1 and 0.85 millimeter dust continuum number counts

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 Added by Gerg\\\"o Popping
 Publication date 2020
  fields Physics
and research's language is English




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We present a new semi-empirical model for the dust continuum number counts of galaxies at 1.1 millimeter and 850 micron. Our approach couples an observationally motivated model for the stellar mass and SFR distribution of galaxies with empirical scaling relations to predict the dust continuum flux density of these galaxies. Without a need to tweak the IMF, the model reproduces the currently available observations of the 1.1 millimeter and 850 micron number counts, including the observed flattening in the 1.1 millimeter number counts below 0.3 mJy citep{Gonzalez2019numbercounts} and the number counts in discrete bins of different galaxy properties. Predictions of our work include : (1) the galaxies that dominate the number counts at flux densities below 1 mJy (3 mJy) at 1.1 millimeter (850 $mu$m) have redshifts between $z=1$ and $z=2$, stellar masses of $sim 5times10^{10}~rm{M}_odot$, and dust masses of $sim 10^{8}~rm{M}_odot$; (2) the flattening in the observed 1.1 millimeter number counts corresponds to the knee of the 1.1 millimeter luminosity function. A similar flattening is predicted for the number counts at 850 $mu$m; (3) the model reproduces the redshift distribution of current 1.1 millimeter detections; (4) to efficiently detect large numbers of galaxies through their dust continuum, future surveys should scan large areas once reaching a 1.1 millimeter flux density of 0.1 mJy rather than integrating to fainter fluxes. Our modeling framework also suggests that the amount of information on galaxy physics that can be extracted from the 1.1 millimeter and 850 $mu$m number counts is almost exhausted.



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Sub/millimiter observations of dusty star-forming galaxies with ALMA have shown that the dust continuum emission occurs generally in compact regions smaller than the stellar distribution. However, it remains to be understood how systematic these findings are, as they often lack of homogeneity in the sample selection, target discontinuous areas with inhomogeneous sensitivities, and suffer from modest $uv$-coverage coming from single array configurations. GOODS-ALMA is a 1.1 mm galaxy survey over a continuous area of 72.42 arcmin$^2$ at a homogeneous sensitivity. In this version 2.0, we present a new low-resolution dataset and its combination with the previous high-resolution dataset from Franco et al. (2018), improving the $uv$-coverage and sensitivity reaching an average of $sigma = 68.4$ $mu$Jy beam$^{-1}$. A total of 88 galaxies are detected in a blind search (compared to 35 in the high-resolution dataset alone), 50% at $rm{S/N_{peak}} geq 5$ and 50% at $3.5 leq rm{S/N_{peak}} leq 5$ aided by priors. Among them, 13/88 are optically dark/faint sources ($H$ or $K$-band dropouts). The sample dust continuum sizes at 1.1 mm are generally compact, with a median effective radius of $R_{rm{e}} = 010 pm 005$ (physical size of $R_{rm{e}} = 0.73 pm 0.29$ kpc, at the redshift of each source). Dust continuum sizes evolve with redshift and stellar mass resembling the trends of the stellar sizes measured at optical wavelengths, albeit a lower normalization compared to those of late-type galaxies. We conclude that for sources with flux densities $S_{rm{1.1mm}} > 1$ mJy compact dust continuum emission at 1.1 mm prevails, and sizes as extended as typical star-forming stellar disks are rare. $S_{rm{1.1mm}} < 1$ mJy sources appear slightly more extended at 1.1 mm, although still generally compact below the sizes of typical star-forming stellar disks.
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