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Probing the early chemical evolution of the Sculptor dSph with purely old stellar tracers

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arxiv 1605.02768 v1 pith:FVAWGRT2 submitted 2016-05-09 astro-ph.GA astro-ph.SR

Probing the early chemical evolution of the Sculptor dSph with purely old stellar tracers

classification astro-ph.GA astro-ph.SR
keywords metallicitydistributionsculptorarcminrrlsstarscentralchemical
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We present the metallicity distribution of a sample of 471 RR Lyrae (RRL) stars in the Sculptor dSph, obtained from the $I$-band Period-Luminosity relation. It is the first time that the early chemical evolution of a dwarf galaxy is characterized in such a detailed and quantitative way, using photometric data alone. We find a broad metallicity distribution (FWHM=0.8 dex) that is peaked at [Fe/H]$\simeq$-1.90 dex, in excellent agreement with literature values obtained from spectroscopic data. Moreover, we are able to directly trace the metallicity gradient out to a radius of $\sim$55 arcmin. We find that in the outer regions (r$>\sim$32 arcmin) the slope of the metallicity gradient from the RRLs (-0.025 dex arcmin$^{-1}$) is comparable to the literature values based on red giant (RG) stars. However, in the central part of Sculptor we do not observe the latter gradients. This suggests that there is a more metal-rich and/or younger population in Sculptor that does not produce RRLs. This scenario is strengthened by the observation of a metal-rich peak in the metallicity distribution of RG stars by other authors, which is not present in the metallicity distribution of the RRLs within the same central area.

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