James Webb Space Telescope Feed Post

JWST/CEERS Sheds Light on Dusty Star-Forming Galaxies: Forming Bulges, Lopsidedness and Outside-In Quenching at Cosmic Noon

RGB (F115W, F200W, F444W) image of the galaxy ID15371 (3.6”× 3.6”) at zspec = 1.921 before (left panel) and after (right panel) PSF-matching. In the left panel, the white ellipses show the features we identified and counted as clumps. In the right panel, the colored dotted lines correspond to the division of the galaxy in homogeneously colored regions and the white filled circle to the PSF size. We investigate the morphology and physical properties of a sample of 22 IR-selected dusty star-forming galaxies at Cosmic Noon (z ~ 2), using James Webb Space Telescope NIRCam images obtained in the EGS field for the Cosmic Evolution Early Release Science survey. The exceptional resolution of the NIRCam images allows us to spatially resolve these galaxies up to 4.4um and identify their bulge/core even when very extinguished by dust. Based on red-green-blue images using the F115W, F200W and F444W filters, we divide each galaxy in several uniformly colored regions, fit their respective Spectral Energy Distribution and measure dust attenuations, stellar masses, star formation rates and ages. After classifying each region as star-forming or quiescent, we assign galaxies to three classes, depending on whether active star-formation is located in the core, in the disk or in both. (i) ~70% of our DSFGs have a compact highly dust attenuated star-forming core that can contain up to 80% of the star-formation of the galaxy but only 20-30% of its stellar mass, and is always surrounded by a larger, less attenuated massive disk (no blue nuggets); (ii) 64% (27%) of disks are significantly (strongly) lopsided, likely due to asymmetric cold gas accretion, major mergers and/or large scale instabilities; (iii) 23% of galaxies have a star-forming core embedded in a quiescent disk, they are undergoing outside-in quenching, often facilitated by their strong lopsidedness inducing small and large scale instabilities; (iv) some galaxies host highly heterogeneous disks in term of RGB colors: these are driven by in-homogeneous dust attenuation; and (v) we find surprising evidence for clump-like substructures being quiescent and/or residing in quiescent regions. This work demonstrates the major impact JWST/NIRCam has on understanding the complexity of the evolution of distant massive galaxies.