Beyond S\'ersic + exponential disc morphologies in the Coma Cluster

Abstract

[abridged] We explore the diversity of internal galaxy structures in the Coma cluster across a wide range of luminosities (-17\,>\,Mg\,>\,-22) and cluster-centric radii (0\,<\,rcluster\,<\,1.3 r200) through analysis of deep Canada-France-Hawaii Telescope i band imaging. We present 2D multi-component decomposition via GALFIT, encompassing a wide range of candidate model morphologies with up to three photometric components. Particular focus is placed on early-type galaxies with outer discs (i.e. S0s), and deviations from simple (`unbroken') exponential discs. Rigorous filtering ensures that each model component provides a statistically significant improvement to the goodness-of-fit. The majority of Coma cluster members in our sample (478 of 631) are reliably fitted by symmetric structural models. Of these, 134 (28\%) are single S\'ersic objects, 143 (30\%) are well-described by 2 component structures, while 201 (42\%) require more complex models. Multi-component S\'ersic galaxies resemble compact psuedobulges (n\,2, Re \, 4 kpc) surrounded by extended Gaussian-like outer structures (Re > 10 kpc). 11\% of galaxies (N=52) feature a break in their outer profiles, indicating `truncated' or `anti-truncated' discs. Beyond the break radius, truncated galaxies are structurally consistent with exponential discs, disfavouring physical truncation as their formation mechanism. Bulge luminosity in anti-truncated galaxies correlates strongly with galaxy luminosity, indicating a bulge-enhancing origin for these systems. Both types of broken disc are found overwhelmingly (>70\%) in `barred' galaxies, despite a low measured bar fraction for Coma (202\%). Thus, galaxy bars play an important role in formation of broken disc structures. No strong variation in galaxy structure is detected with projected cluster-centric radius.