Bibcode
Carretero, C.; Vazdekis, A.; Beckman, J. E.
Referencia bibliográfica
Monthly Notices of the Royal Astronomical Society, Volume 375, Issue 3, pp. 1025-1033.
Fecha de publicación:
3
2007
Número de citas
14
Número de citas referidas
11
Descripción
We present a detailed stellar population analysis of 27 massive
elliptical galaxies within four very rich clusters at redshift z ~ 0.2:
A115, A655, A963 and A2111. Using the new, high-resolution stellar
populations models developed in our group, we obtained accurate
estimates of the mean luminosity-weighted ages and relative abundances
of CN, Mg and Fe. We derived the age, [CN/H], [Mg/H], [Fe/H] and the
abundance ratios [CN/Fe] and [Mg/Fe] as functions of the galaxy velocity
dispersion, σ. We have found that [CN/H] and [Mg/H] are correlated
with σ while [Fe/H] and Log(age) are not. In addition, both
abundance ratios [CN/Fe] and [Mg/Fe] increase with σ. Furthermore,
the [CN/H]-σ and [CN/Fe]-σ slopes are steeper for galaxies
in very rich clusters than those in the less dense Virgo and Coma
clusters. On the other hand, [Mg/H]-σ and [Mg/Fe]-σ slopes
keep constant as functions of the environment. Our results are
compatible with a scenario in which the stellar populations of massive
elliptical galaxies, independently of their environment and mass, had
formation time-scales shorter than ~1 Gyr. This result implies that
massive elliptical galaxies have evolved passively since, at least, as
long ago as z ~ 2. For a given galaxy mass, the duration of star
formation is shorter in those galaxies belonging to more dense
environments, whereas the mass-metallicity relation appears to be also a
function of the cluster properties: the denser the environment is, the
steeper are the correlations. Finally, we show that the abundance ratios
[CN/Fe] and [Mg/Fe] are the key `chemical clocks' to infer the star
formation history time-scales in ellipticals. In particular, [Mg/Fe]
provides an upper limit for those formation time-scales, while [CN/Fe]
appears to be the most suitable parameter to resolve them in elliptical
galaxies with σ < 300 km s-1.