The Buildup of the Hubble Sequence in the Cosmos Field
Kneib, J. -P.; Aussel, H.; Le Floc'h, E.; Sanders, D. B.; Ilbert, O.; Taniguchi, Y.; Sargent, M. T.; Salvato, M.; Bolzonella, M.; Oesch, P. A.; Capak, P.; Koekemoer, A. M.; Carollo, C. M.; McCracken, H. J.; Scoville, N.; Scarlata, C.; Thompson, D.; Massey, R.; Pozzetti, L.; Rhodes, J.; Leauthaud, A.; Lilly, S. J.; Renzini, A.; Aller, M. C.; Bundy, K.; Hahn, O.; Kovač, K.; Sheth, K.; Feldmann, R.; Bschorr, T.
Switzerland, Germany, United States, France, Italy, United Kingdom, Japan
Abstract
We use ~8600 COSMOS galaxies at mass scales >5 × 1010 M sun to study how the morphological mix of massive ellipticals, bulge-dominated disks, intermediate-bulge disks, disk-dominated galaxies, and irregular systems evolves from z = 0.2 to z = 1. The morphological evolution depends strongly on mass. At M > 3 × 1011 M sun, no evolution is detected in the morphological mix: ellipticals dominate since z = 1, and the Hubble sequence has quantitatively settled down by this epoch. At the 1011 M sun mass scale, little evolution is detected, which can be entirely explained by major mergers. Most of the morphological evolution from z = 1 to z = 0.2 takes place at masses 5 × 1010-1011 M sun, where (1) the fraction of spirals substantially drops and the contribution of early types increases. This increase is mostly produced by the growth of bulge-dominated disks, which vary their contribution from ~10% at z = 1 to >30% at z = 0.2 (for comparison, the elliptical fraction grows from ~15% to ~20%). Thus, at these masses, transformations from late to early types result in diskless elliptical morphologies with a statistical frequency of only 30%-40%. Otherwise, the processes which are responsible for the transformations either retain or produce a non-negligible disk component. (2) The disk-dominated galaxies, which contribute ~15% to the intermediate-mass galaxy population at z = 1, virtually disappear by z = 0.2. The merger rate since z = 1 is too low to account for the disappearance of these massive disk-dominated systems, which most likely grow a bulge via secular evolution.