Characteristic Scales in Galaxy Formation

Abstract

Recent data, e.g. from SDSS and 2dF, reveal a robust bi-modality in the distribution of galaxy properties, with a characteristic transition scale at stellar mass M∗ ∼ 3 × 10M (near L∗), corresponding to virial velocity V ∼ 100 km s−1. Smaller galaxies tend to be blue disks of young populations. They define a “fundamental line” of decreasing surface brightness, metallicity and velocity with decreasing M∗, which extends to the smallest dwarf galaxies. Galaxies above the critical scale are dominated by red spheroids of old populations, with roughly constant high surface brightens and metallicity, and they tend to host AGNs. A minimum in the virial M/L is obtained at the same magic scale. This bi-modality can be the combined imprint of several different physical processes. On smaller scales, disks are built by cold flows, and supernova feedback is effective in regulating star formation. On larger scales, the infalling gas is heated by a virial shock and star formation can be suppressed by AGN feedback. Another feedback mechanism – gas evaporation due to photo-ionization – may explain the existence of totally dark halos below V ∼ 30 km s−1. The standard cooling barriers are responsible for the loose upper and lower bounds for galaxies: 10 < V < 300 km s−1.