The origin of bulges and discs in the CALIFA survey: I. Morphological evolution

TL;DR

This study investigates the formation and evolution of non-barred disc galaxies using spectro-photometric decomposition, revealing insights into their structural and stellar population properties over cosmic time.

Contribution

Introduces the C2D decomposition code and analyzes CALIFA survey data to understand the morphological evolution of bulges and discs in non-barred galaxies.

Findings

Bulge-to-total luminosity ratio correlates with galaxy stellar mass.

Disc component increases since redshift z<1 in massive galaxies.

Mass-size relation shows an upturn at high stellar masses.

Abstract

This series of papers aims at understanding the formation and evolution of non-barred disc galaxies. We use the new spectro-photometric decomposition code, C2D, to separate the spectral information of bulges and discs of a statistically representative sample of galaxies from the CALIFA survey. Then, we study their stellar population properties analising the structure-independent datacubes with the Pipe3D algorithm. We find a correlation between the bulge-to-total ($B/T$) luminosity (and mass) ratio and galaxy stellar mass. The $B/T$ mass ratio has only a mild evolution with redshift, but the bulge-to-disc ($B/D$) mass ratio shows a clear increase of the disc component since redshift $z < 1$ for massive galaxies. The mass-size relation for both bulges and discs describes an upturn at high galaxy stellar masses (log{(M_{\star}/M_{\sun})} > 10.5). The relation holds for bulges but not for discs when using their individual stellar masses. We find a negligible evolution of the mass-size relation for both the most massive (log{(M_{\star \rm ,b,d}/M_{\sun})} > 10) bulges and discs. For lower masses, discs show a larger variation than bulges. We also find a correlation between the S\'ersic index of bulges and both galaxy and bulge stellar mass, which does not hold for the disc mass. Our results support an inside-out formation of nearby non-barred galaxies, and they suggest that i) bulges formed early-on and ii) they have not evolved much through cosmic time. However, we find that the early properties of bulges drive the future evolution of the galaxy as a whole, and particularly the properties of the discs that eventually form around them.