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تسجيل مستخدم جديدNew Light on the Formation and Evolution of M31 and its Globular Cluster System
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Thomas H. Puzia
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We present spectroscopic ages, metallicities, and [alpha/Fe] ratios for 70 globular clusters in M31 that were derived from Lick line-index measurements. In addition to a population of old (>10 Gyr) globular clusters with a wide range of metallicities, from about -2.0 dex to solar values, we find evidence for a population of intermediate-age globular clusters with ages between ~5 and 8 Gyr and a mean metallicity around [Z/H]=-0.6. We also confirm the presence of young M31 globular clusters that were recently identified by Beasley et al. (2004), which have ages <1 Gyr and relatively high metallicities around -0.4 dex. The M31 globular cluster system has a clearly super-solar mean [alpha/Fe]=0.14pm0.04 dex. Intermediate-age and young objects show roughly solar abundance ratios. We find evidence for an age-[alpha/Fe] relation in the sense that younger clusters have smaller mean [alpha/Fe] ratios. From a comparison of indices, mostly sensitive to carbon and/or nitrogen abundance, with SSP model predictions for nitrogen-enhanced stellar populations, we find a dichotomy in nitrogen enhancement between young and old M31 globular clusters. The indices of objects older than 5 Gyr are consistent with a factor of three or higher in nitrogen enhancement compared to their younger counterparts. Using kinematical data from Morrison et al. (2004) we find that the globular cluster sub-population with halo kinematics is old (>9 Gyr), has a bimodal metallicity distribution, and super-solar [alpha/Fe]. Disk globular clusters have a wider range of ages, are on average more metal-rich, and have a slightly smaller mean [alpha/Fe] ratio. (abridged)
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