1,189 research outputs found
Testing the Least Action Principle in an Omega_0=1 Universe
The least action principle (LAP) is a dynamically rigorous method for
deriving the history of galaxy orbits. In particular it is an Omega_0 test,
predicting current epoch galaxy velocities as a function of position and of the
cosmological background. It is most usefully applied to in--falling structures,
such as the local group, where its application indicates that the preferred
cosmological model is Omega_0 = 0.1 and h=0.75 (h is the Hubble parameter in
units of 100 Km s^-1 Mpc^-1). The method assumes that all the mass acts as if
it were distributed as the visible galaxies. We test the reliability of the LAP
to Local Group-like systems extracted from Omega_0=1 N--body simulations. While
the orbits of the galaxies are qualitatively well reconstructed, the LAP
systematically underestimates the mass of the system. This failure is
attributed to the presence of extended halos weakly clustered around visible
galaxies which prevent a large fraction of the group mass from being detected
by the LAP technique. We conclude that the LAP method cannot rule out an
Omega_0=1 value on the Local Group scale. Better constraints on Omega_0 may be
obtained by applying this technique to in--falling systems, such as clusters,
containing objects with separations large compared to galaxy sizes.Comment: accepted by APJ, uuencoded-compressed-tarred PostScript file
including figures. SISSA Ref. 56/94/
The CFHTLS Deep Catalog of Interacting Galaxies I. Merger Rate Evolution to z=1.2
We present the rest-frame optical galaxy merger fraction between 0.2<z<1.2,
as a function of stellar mass and optical luminosity, as observed by the
Canada-France-Hawaii Telescope Legacy Deep Survey (CFHTLS-Deep). We developed a
new classification scheme to identify major galaxy-galaxy mergers based on the
presence of tidal tails and bridges. These morphological features are signposts
of recent and ongoing merger activity. Through the visual classification of all
galaxies, down to i_vega<22.2 (~27,000 galaxies) over 2 square degrees, we have
compiled the CFHTLS Deep Catalog of Interacting Galaxies, with ~1600 merging
galaxies. We find the merger fraction to be 4.3% +/-0.3% at z~0.3 and 19.0%
+/-2.5% at z~1, implying evolution of the merger fraction going as (1+z)^m,
with m=2.25 +/-0.24. This result is inconsistent with a mild or non-evolving
(m4sigma level of confidence. A mild trend, where massive
galaxies with M>10^10.7 M_sun are undergoing fewer mergers than less massive
systems M~10^10 M_sun), consistent with the expectations of galaxy assembly
downsizing is observed. Our results also show that interacting galaxies have on
average SFRs double that found in non-interacting field galaxies. We conclude
that (1) the optical galaxy merger fraction does evolve with redshift, (2) the
merger fraction depends mildly on stellar mass, with lower mass galaxies having
higher merger fractions at z<1, and (3) star formation is triggered at all
phases of a merger, with larger enhancements at later stages, consistent with
N-body simulations.Comment: e.g.: 17 pages, 14 figures, accepted for publication in Ap
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