FOSSIL EVIDENCE FOR THE TWO-PHASE FORMATION OF ELLIPTICAL GALAXIES

• Published in: Astrophysical journal. Letters Vol. 768; no. 2; pp. 1 - 5
• Main Authors: Huang, Song, Ho, Luis C, Peng, Chien Y, Li, Zhao-Yu, Barth, Aaron J
• Format: Journal Article
• Language: English
• Published: United States 10.05.2013
• Subjects: ASTROPHYSICS, COSMOLOGY AND ASTRONOMY; Construction; DECOMPOSITION; DENSITY; Dissipation; DISTRIBUTION; ELLIPTICAL CONFIGURATION; Elliptical galaxies; Envelopes; EVOLUTION; FOSSILS; GALAXIES; MASS; PHOTOMETRY; RED SHIFT; STOCHASTIC PROCESSES; Substructures; SURFACES
• ISSN: 2041-8205; 2041-8213
• DOI: 10.1088/2041-8205/768/2/L28

Massive early-type galaxies (ETGs) have undergone dramatic structural evolution over the last 10 Gyr. A companion paper shows that nearby elliptical galaxies with M[low *] [> or =, slanted] 1.3 x 10 super(11) M sub([middot in circle]) generically contain three photometric subcomponents: a compact inner component with effective radius R sub(e) [<, ~] 1 kpc, an intermediate-scale middle component with R sub(e) [approximate] 2.5 kpc, and an extended outer envelope with R sub(e) 10 kpc. Here we attempt to relate these substructures with the properties of ETGs observed at higher redshifts. We find that a hypothetical structure formed from combining the inner and middle components of local ellipticals follows a strikingly tight stellar mass-size relation, one that resembles the distribution of ETGs at z [approximate] 1. Outside of the central kpc, the median stellar mass surface density profiles of this composite structure agree closest with those of massive galaxies that have similar cumulative number density at 1.5 < z < 2.0 within the uncertainty. We propose that the central substructures in nearby ellipticals are the evolutionary descendants of the "red nuggets" formed under highly dissipative ("wet") conditions at high redshifts, as envisioned in the initial stages of the two-phase formation scenario recently advocated for massive galaxies. Subsequent accretion, plausibly through dissipationless ("dry") minor mergers, builds the outer regions of the galaxy identified as the outer envelope in our decomposition. The large scatter exhibited by this component on the stellar mass-size plane testifies to the stochastic nature of the accretion events.