On the Use of Field RR Lyrae as Galactic Probes. III. The   $\alpha$-element abundances

J. Crestani (1,2,3); V.F. Braga (3,4); M. Fabrizio (3,4); G. Bono; (2,3); C. Sneden (5); G.W. Preston (6); I. Ferraro (3); G. Iannicola (3); M.; Nonino (7); G. Fiorentino (3); F. Th\'evenin (8); B. Lemasle (9); Z. Prudil; (8); A. Alves-Brito (1); G. Altavilla (3,4); B. Chaboyer (10); M. Dall'Ora; (11); V. D'Orazi (12,13); C.K. Gilligan (10); E. Grebel (8); A.J. Koch-Hansen; (9); H. Lala (9); M. Marengo (14); S. Marinoni (3,4); P.M. Marrese (3,4),; C.E. Mart\'inez-V\'azquez (15); N. Matsunaga (16); M. Monelli (17); J.P.; Mullen (14); J. Neeley (18); R. da Silva (3,4); P.B. Stetson (19); M. Salaris; (20); J. Storm (21); E. Valenti (22); M. Zoccali (23,24) ((1) Departamento de; Astronomia; Universidade Federal do Rio Grande do Sul; Porto Alegre; Brazil,; (2) Dipartimento di Fisica; Universit\`a di Roma Tor Vergata; Roma; Italy,; (3) INAF-Osservatorio Astronomico di Roma; Monte Porzio Catone; Italy; (4); Space Science Data Center; Roma; Italy; (5) Department of Astronomy and; McDonald Observatory; The University of Texas; Austin; TX; USA; (6) The; Observatories of the Carnegie Institution for Science; Pasadena; CA; USA; (7); INAF-Osservatorio Astronoico di Trieste; Trieste; Italy; (8) Universit\'e de; Nice Sophia-antipolis; CNRS; Observatoire de la C\^ote d'Azur; Laboratoire; Lagrange; Nice; France; (9) Astronomisches Rechen-Institut; Zentrum f\"ur; Astronomie der Universit\"at Heidelberg; Heidelberg; Germany; (10) Department; of Physics; Astronomy; Dartmouth College; Hanover; USA; (11); INAF-Osservatorio Astronomico di Capodimonte; Napoli; Italy; (12); INAF-Osservatorio Astronomico di Padova; Padova; Italy; (13) School of; Physics; Astronomy; Monash University; Clayton; Melbourne; Australia; (14); Department of Physics; Astronomy; Iowa State University; Ames; IA; USA,; (15) Cerro Tololo Inter-American Observatory; NSF's National Optical-Infrared; Astronomy Research Laboratory; La Serena; Chile; (16) Department of; Astronomy; The University of Tokyo; Tokyo; Japan; (17) Instituto de; Astrof\'isica de Canarias; La Laguna; Tenerife; Spain; (18) Department of; Physics; Florida Atlantic University; Boca Raton; FL; USA; (19) Herzberg; Astronomy; Astrophysics; National Research Council; Victoria; BC; Canada,; (20) Astrophysics Research Institute; Liverpool John Moores University,; Liverpool; UK; (21) Leibniz-Institut f\"ur Astrophysik Potsdam; Potsdam,; Germany; (22) European Southern Observatory; Garching bei Munchen; Germany,; (23) Instituto Milenio de Astrof\'isica; Santiago; Chile; (24) Pontificia; Universidad Catolica de Chile; Instituto de Astrofisica; Santiago; Chile)

arXiv:2104.08113·astro-ph.GA·June 23, 2021

On the Use of Field RR Lyrae as Galactic Probes. III. The $\alpha$-element abundances

J. Crestani (1,2,3), V.F. Braga (3,4), M. Fabrizio (3,4), G. Bono, (2,3), C. Sneden (5), G.W. Preston (6), I. Ferraro (3), G. Iannicola (3), M., Nonino (7), G. Fiorentino (3), F. Th\'evenin (8), B. Lemasle (9), Z. Prudil, (8), A. Alves-Brito (1), G. Altavilla (3,4)

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TL;DR

This study provides a comprehensive analysis of alpha-element and iron abundances in 208 field RR Lyrae stars, revealing trends that inform our understanding of the Galaxy's early chemical evolution and dwarf galaxy contributions.

Contribution

It presents the largest homogeneous dataset of alpha-element abundances in RR Lyrae stars, highlighting new metallicity-dependent alpha-element depletion patterns and similarities with dwarf galaxy stellar populations.

Findings

01

Field RR Lyrae stars are more alpha-poor at higher metallicities.

02

At low metallicities, RR Lyrae stars are more alpha-enhanced.

03

Similar abundance patterns link RR Lyrae stars to dwarf galaxy populations.

Abstract

We provide the largest and most homogeneous sample of $α$ -element (Mg, Ca, Ti) and iron abundances for field RR Lyrae (RRLs, 162 variables) by using high-resolution spectra. The current measurements were complemented with similar abundances available in the literature for 46 field RRLs brought to our metallicity scale. We ended up with a sample of old (t $\geq$ 10 Gyr), low-mass stellar tracers (208 RRLs: 169 fundamental, 38 first overtone, 1 mixed mode) covering three dex in iron abundance (-3.00 $\leq$ [Fe/H] $\leq$ 0.24). We found that field RRLs are $\sim$ 0.3 dex more $α$ -poor than typical Halo tracers in the metal-rich regime, ([Fe/H] $\geq$ -1.2) while in the metal-poor regime ([Fe/H] $\leq$ -2.2) they seem to be on average $\sim$ 0.1 dex more $α$ -enhanced. This is the first time that the depletion in $α$ -elements for solar iron abundances is detected on the basis of a large,…

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