Fluorine variations in the globular cluster NGC 6656 (m22): Implications for internal enrichment timescales

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Abstract

Observed chemical (anti)correlations in proton-capture elements among globular cluster stars are presently recognized as the signature of self-enrichment from now extinct, previous generations of stars. This defines the multiple population scenario. Since fluorine is also affected by proton captures, determining its abundance in globular clusters provides new and complementary clues regarding the nature of these previous generations and supplies strong observational constraints to the chemical enrichment timescales. In this paper, we present our results on near-infrared CRIRES spectroscopic observations of six cool giant stars in NGC 6656 (M22): the main objective is to derive the F content and its internal variation in this peculiar cluster, which exhibits significant changes in both light- and heavy-element abundances. Across our sample, we detected F variations beyond the measurement uncertainties and found that the F abundances are positively correlated with O and anticorrelated with Na, as expected according to the multiple population framework. Furthermore, our observations reveal an increase in the F content between the two different sub-groups, s-process rich and s-process poor, hosted within M22. The comparison with theoretical models suggests that asymptotic giant stars with masses between 4 and 5 M⊙ are responsible for the observed chemical pattern, confirming evidence from previous works: the difference in age between the two sub-components in M22 must be not larger than a few hundred Myr. © 2013. The American Astronomical Society. All rights reserved.

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D’Orazi, V., Lucatello, S., Lugaro, M., Gratton, R. G., Angelou, G., Bragaglia, A., … Mucciarelli, A. (2013). Fluorine variations in the globular cluster NGC 6656 (m22): Implications for internal enrichment timescales. Astrophysical Journal, 763(1). https://doi.org/10.1088/0004-637X/763/1/22

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