Morphological Demographics of Galaxies at z 10-16: Log-Normal Size Distribution and Exponential Profiles Consistent with the Disk Formation Scenario

Abstract

We homogeneously investigate the morphological properties of 169 galaxies at z10-16 with deep JWST NIRCam images employing our established techniques of GALFIT modeling and uncertainty evaluation (systematics+statistics). We obtain effective radii r e ranging 20-500 pc, with a distribution significantly broader than the scatter made by the uncertainties. We find that the r e distribution is well described by a log-normal distribution with a mean of r e=133+13-12 pc and a standard deviation of σ lnr e = 0.52 0.08. The standard deviation is comparable to that of local galaxies, indicating no significant evolution over z 0-10. We also find that the axis ratio distribution is nearly uniform, statistically similar to that of local spirals. We estimate the virial radius r vir from the stellar masses via the star-formation main sequence and stellar-to-halo mass relation, obtaining a stellar-to-halo size ratio r e/r vir = 0.015+0.015-0.005, which is comparable to those of star-forming galaxies in the local and low-z Universe. Our results of 1) the log-normal r e distribution, 2) the uniform axis ratio distribution, and 3) a mean radial profile consistent with an exponential profile (n=1.30.6) suggest that galaxies at z10-16 generally follow the classical galaxy disk formation scenario with a specific disk angular momentum fraction of j d / m d 0.5-1. Interestingly, we identify two remarkable outliers GN-z11 (z spec=10.60) and GHZ2 (z spec=12.34) with r e=55+5-6 pc and 3911 pc, respectively, that may not be explained by disk structures but by AGN or compact star-forming galaxies merging underway in short periods of time, as reproduced in numerical simulations.

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