To Ba or not to Ba: Observational constraints to the evolution of barium stars

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To Ba or not to Ba: Observational constraints to the evolution of barium stars Ana Escorza - ImBaSE 2017 + H. Van Winckel, L. Siess, A. Jorissen, H. Boffin, S. Van Eck...

Barium stars

1 Barium (Ba) stars G- and K-type giants which present overabundances of s-process elements (e.g., Ba) on their surface. They could not have synthesised them

1 Barium (Ba) stars G- and K-type giants which present overabundances of s-process elements (e.g., Ba) on their surface. They could not have synthesised them s-process The slow-neutron-capture (s-) process of nucleosynthesis takes place in the AGB phase. Ba stars

Barium (Ba) stars Formed through binary interaction in a lowor intermediate-mass binary. The less evolved secondary gets polluted with AGB products via wind and/or RLOF. 2

2 Barium (Ba) stars Formed through binary interaction in a lowor intermediate-mass binary. The less evolved secondary gets polluted with AGB products via wind and/or RLOF. Remaining uncertainties: Initial conditions Mass-transfer scenario Evolutionary links... Talks by H.M.J.Boffin, O.Pols

Goal of our research

3 Goal of our research Why barium stars? Observational vs. theoretical HR and e-logp diagrams Improving models & increase our understanding of evolution and interaction in low- and intermediatemass binaries. Known to be formed by binary interaction with a former AGB companion We can use both observed orbital parameters and chemical abundances to put constraints on the models.

3 Goal of our research Observational vs. theoretical HR and e-logp diagrams Gaia (picture from http://www.cosmos.esa.int/web/gaia/the-mission) Improving models & increase our understanding of evolution and interaction in low- and intermediatemass binaries. (Raskin et el. 2011) HERMES spectrograph @ Mercator (picture by P. I. Pápics)

The TGAS HR diagram of Ba stars Escorza et al., in prep Gaia (picture from http://www.cosmos.esa.int/web/gaia/the-mission)

4 Sample selection 323 TGAS stars Ba and related star samples from - Lu et al. (1983 & 1991) - Bartkevicius (1983) - North et al. (2000) Part of the Tycho2 catalogue. slide by Lennart Lindegren Part of TGAS (Tycho-Gaia Astrometric Solution) Error(parallax) < ⅓ parallax. DR1, Gaia Collaboration et al. (2016a) TGAS, Lindegren et al. (2016)

4 Sample selection 323 TGAS stars 114 bright Hipparcos stars slide by Lennart Lindegren DR1, Gaia Collaboration et al. (2016a) TGAS, Lindegren et al. (2016) Hipparcos, ESA (1997)

Determination of Teff and L Spectral energy distribution (SED) fitting We retrieve available photometry from SIMBAD 2 minimization over a grid of MARCS model atmospheres Gustafsson et al. (2008) 5

Determination of Teff and L Spectral energy distribution (SED) fitting We retrieve available photometry from SIMBAD 2 minimization over a grid of MARCS model atmospheres Gustafsson et al. (2008) Teff, logg, metallicity and E(B-V) Fitting tool by P. Degroote 5

Determination of Teff and L Spectral energy distribution (SED) fitting We retrieve available photometry from SIMBAD 2 minimization over a grid of MARCS model atmospheres Gustafsson et al. (2008) Too many free parameters: Teff, logg, metallicity and E(B-V) Fixed [Fe/H] = -0.25, where the distribution of known metallicities for Ba stars peaks Galactic 3D extinction maps from Gontcharov et al. (2012) Fitting tool by P. Degroote 5

HR diagram of Ba stars Evolutionary tracks with [Fe/H] = -0.25 computed with STAREVOL (Siess 2006) slide by Lennart Lindegren 6

6 HR diagram of Ba stars Evolutionary tracks with [Fe/H] = -0.25 computed with STAREVOL (Siess 2006) - sgch stars occupy the same region on the HRD that dba stars. - Some targets appear at high masses. - Strong concentration of Ba stars in the red clump. slide by Lennart Lindegren

What can we learn from this?

Mass distribution of Ba stars Mass estimated by interpolating in the theoretical tracks. Grid with 17 106 points characterised by a value of T, L and MT,L slide by Lennart Lindegren We take into account the time that a star spends at a given location of the HRD. 7

Mass distribution of Ba stars Mass estimated by interpolating in the theoretical tracks. Grid with 17 106 points characterised by a value of T, L and MT,L slide by Lennart Lindegren We take into account the time that a star spends at a given location of the HRD. Uncertainties in Teff and L have a strong effect 7

Mass distribution of Ba stars: metallicity Distribution of metallicities if Ba stars found in the literature slide by Lennart Lindegren 8

Mass distribution of Ba stars: metallicity Mass-metallicity degeneracy slide by Lennart Lindegren 8

Mass distribution of Ba stars: metallicity The effect of metallicity is also very important slide by Lennart Lindegren Spectroscopically determined metallicities are a requirement to get information about individual masses. Data for 330 stars of the sample is available in the literature (+ we have HERMES!) Talk by D.Karinkuzhi 8

Mass distribution of Ba stars: normal giants? 9 - Both distributions peak at similar values. Accumulation in the clump does not seem to be specific to Ba stars. - Deficit of low mass Ba stars. Probably early shrinkage of the orbit. - Excess of high mass Ba stars. Pollution of the sample. slide by Lennart Lindegren

10 Mass distribution of Ba stars: Populations Barium index (Warner, 1965) reflects the strength of the Ba lines, based on visual inspection, on a scale from Ba1 to Ba5. No significant difference between mild (Ba1 - Ba2) and strong (Ba3 - Ba5) barium stars. slide by Lennart Lindegren Lü (1991) introduced some stars with Ba < 1, which happen to populate the high mass tail.

Location in the HRD and orbital period

HRD and orbital period Orbital elements from Jorissen et al. (1998), Jorissen et al. (2016) and Escorza et al. (2017; in prep.) Two subsamples: - Pre-RGB: log L/L 1.4 slide by Lennart Lindegren - Red clump: 1.4 < log L/L 2.2 11

HRD and orbital period Orbital elements from Jorissen et al. (1998), Jorissen et al. (2016) and Escorza et al. (2017; in prep.) Two subsamples: - Pre-RGB: log L/L 1.4 slide by Lennart Lindegren - Red clump: 1.4 < log L/L 2.2 Tendency for larger periods in the red clump, as compared to systems lying below. 11

Conclusions

12 Conclusions HR diagram for barium stars Mass distribution. - The effects of the uncertainties and of the metallicity prevent us from getting information about individual objects. Don t forget the uncertainties in evolutionary models! - Ba giants seem to evolve as normal red giants. - Subgiant CH and dwarf Ba stars occupy the same region of the HRD. - Strong and mild barium stars have similar mass distributions. - Correlation between the location in the HRD and the orbital period of Ba stars. Tendency for larger periods in the core He burning phase. slide by Lennart Lindegren

Thank you for your attention Ana Escorza - ImBaSE 2017

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