In the paper Exploring the evolutionary paths of the most massive galaxies since z~2 (ApJ 2008, 687, 50), we have analyzed the Spitzer/MIPS 24 μm emission of a sample of massive galaxies (M>1011 M) at 0≤z≤2 segregated by morphology.

The two figures above are extracted from this paper. The first figure (left) depicts 4 examples of the galaxies in our sample. Left panels show 10"×10" RGB composite images built from HST/ACS v and i frames. In the middle column, MIPS 24 μm images of size 40"×40" are depicted, with the red square showing the area covered by the ACS postage stamp. In all images, North is up and East is left. The right columns show the SEDs of each galaxy, fitted to stellar population and dust emission models which are used to estimate photometric redshifts, stellar masses and SFRs (these parameters are given in each SED plot). The two upper rows show examples of disk-like galaxies: EGS142126.97+531137.4, a galaxy at z=0.67; and EGS142013.18+525925.0, lying at z=1.65. The two lower rows show examples of spheroid-like galaxies: EGS142021.47+525543.4, a galaxy at z=0.63, and EGS142125.76+531622.8, placed at z=1.70.

Interestingly, not only most (more than 90%) disk-like massive galaxies are detected by MIPS (revealing the presence of dust-enshrouded star formation in these systems), but also around 50% of spheroids have MIPS counterparts, especially at z>1, even when rest-frame optical colors reveal that they are dead and evolving passively.

The second figure above (right) shows the specific SFRs as a function of redshift and morphology (for galaxies not identified as AGN) for our sample. Galaxies detected at 24 μm are plotted with open (disks) and filled (spheroids) black circles, while gray symbols show upper limits for sources not detected by MIPS. Red and blue crosses represent the median and quartiles for the distribution of specific SFRs in different redshift ranges. The red widest lines refer to spheroids and the blue narrowest lines to disky galaxies. Green curves show the expected positions of galaxies which would multiply their stellar mass by 5/4, 2, and 4 between their redshift and z=0 if they maintained a constant SFR. Horizontal dashed lines show constant SFR values for the median stellar mass of our sample (1.6×1011 M).

Based on the measured specific SFRs, we estimate that MIPS detected spheroid-like galaxies have doubled (at the most, depending on the burst durations) their stellar mass due to newly-born stars alone from z=2 to z=0.2. Most of this mass increase (60%) occurs at z>1, where specific SFRs are as high as 0.4 Gyr-1. Disk-like galaxies have tripled (at the most) their stellar mass by newly-formed stars at z<2, with a more steady growth rate as a function of redshift.

These figures contrast with the size increments measured by Trujillo et al. (2007) for the same sample: massive spheroid-like galaxies have increased their size up to a factor of ~5.5 from z=2 to z=0 (10 Gyr), while massive disks have increased their size by a ~2.5 factor in the same period. If star formation works in the same way in making both spheroid and disk-like galaxies grow in size, clearly there should be another mechanism (mergers?, adiabatic expansion?) helping (more noticeably) the spheroids (which form less new stars than disks between z=2 and the present, but grow more) to increase their size.

Previous papers in this webpage

The Stellar Mass Assembly of Galaxies from z = 0 to z = 4: Analysis of a Sample Selected in the Rest-Frame Near-Infrared with Spitzer

Created on Wed Jun 10 16:13:02 CEST 2009
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