NGC 2243 (also ESO 426-SC16 and OCL 644) is a magnitude +9.4 open cluster located 14,500 light-years away in the constellation Canis Major.
The cluster was discovered by Scottish astronomer James Dunlop using a 22.86 cm (9 inch) reflector from Paramatta, New South Wales, on the 24th May 1826.
Right Ascension 06h 29m 34.4s, Declination -31° 16' 53"
Title: Lithium abundance in the metal-poor open cluster NGC 2243 Authors: P. Francois, L. Pasquini, K. Biazzo, P. Bonifacio, R. Palsa
Lithium is a fundamental element for studying the mixing mechanisms acting in the stellar interiors, for understanding the chemical evolution of the Galaxy and the Big Bang nucleosynthesis. The study of Li in stars of open clusters (hereafter OC) allows a detailed comparison with stellar evolutionary models and permits us to trace its galactic evolution. The OC NGC 2243 is particularly interesting because of its low metallicity ([Fe/H]=-0.54 ±0.10 dex). We measure the iron and lithium abundance in stars of the metal-poor OC NGC 2243. The first aim is to determine whether the Li dip extends to such low metallicities, the second is to compare the results of our Li analysis in this OC with those present in 47 Tuc, a globular cluster of similar metallicity. We performed a detailed analysis of high-resolution spectra obtained with the multi-object facility FLAMES at the ESO VLT 8.2m telescope. Lithium abundance was derived through line equivalent widths and the OSMARCS atmosphere models. We determine a Li dip center of 1.06 solar masses, which is much smaller than that observed in solar metallicity and metal-rich clusters. This finding confirms and strengthens the conclusion that the mass of the stars in the Li dip strongly depends on stellar metallicity. The mean Li abundance of the cluster is \log n(Li)=2.70 dex, which is substantially higher than that observed in 47 Tuc. We estimated an iron abundance of [Fe/H]=-0.54 ±0.10 dex for NGC 2243, which is similar (within the errors) to previous findings. The [ \alpha/Fe] content ranges from 0.00 ±0.14 for Ca to 0.20 ±0.22 for Ti, which is low when compared to thick disk stars and to Pop II stars, but compatible with thin disk objects. We found a mean radial velocity of 61.9 ± 0.8 \kms for the cluster.