The contribution of major mergers to galaxy mass assembly along cosmic time
is an important ingredient to the galaxy evolution scenario. We aim to measure
the evolution of the merger rate for both luminosity/mass selected galaxy
samples and investigate its dependence with the local environment. We use a
sample of 10644 spectroscopically observed galaxies from the zCOSMOS redshift
survey to identify pairs of galaxies destined to merge, using only pairs for
which the velocity difference and projected separation of both components with
a confirmed spectroscopic redshift indicate a high probability of merging. We
have identified 263 spectroscopically confirmed pairs with r_p^{max} = 100
h^{-1} kpc. We find that the density of mergers depends on luminosity/mass,
being higher for fainter/less massive galaxies, while the number of mergers a
galaxy will experience does not depends significantly on its intrinsic
luminosity but rather on its stellar mass. We find that the pair fraction and
merger rate increase with local galaxy density, a property observed up to
redshift z=1. We find that the dependence of the merger rate on the luminosity
or mass of galaxies is already present up to redshifts z=1, and that the
evolution of the volumetric merger rate of bright (massive) galaxies is
relatively flat with redshift with a mean value of 3*10^{-4} (8*10^{-5}
respectively) mergers h^3 Mpc^{-3} Gyr^{-1}. The dependence of the merger rate
with environment indicates that dense environments favors major merger events
as can be expected from the hierarchical scenario. The environment therefore
has a direct impact in shapping-up the mass function and its evolution
therefore plays an important role on the mass growth of galaxies along cosmic
time.Comment: submitted to A&A, 17 pages, 12 figure