2019
DOI: 10.1051/0004-6361/201935296
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Observational evidence of third dredge-up occurrence in S-type stars with initial masses around 1 M

Abstract: Context. S stars are late-type giants with spectra showing characteristic molecular bands of ZrO in addition to the TiO bands typical of M stars. Their overabundance pattern shows the signature of s-process nucleosynthesis. Intrinsic, technetium (Tc)-rich S stars are the first objects, on the Asymptotic Giant Branch (AGB), to undergo third dredge-up (TDU) events. Gaia exquisite parallaxes now allow to precisely locate these stars in the Hertzsprung-Russell (HR) diagram. Here we report on a population of low-ma… Show more

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Cited by 23 publications
(27 citation statements)
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“…f over = 0.14, D min = 10 7 cm 2 s −1 , and p = 1/2, where f over controls the extent of the mixing, D min is the value of the diffusion coefficient at the innermost boundary of the diffusive region, and p is an additional free parameter describing the shape of the diffusion profile. As shown in Shetye et al (2019), this adopted set of diffusion parameters gives rise to early TDU episodes and s-process enrichments in stars with masses as low as 1 M and compatible with observations.…”
Section: Models Of S-and I-processes In Low-mass Agb Starssupporting
confidence: 83%
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“…f over = 0.14, D min = 10 7 cm 2 s −1 , and p = 1/2, where f over controls the extent of the mixing, D min is the value of the diffusion coefficient at the innermost boundary of the diffusive region, and p is an additional free parameter describing the shape of the diffusion profile. As shown in Shetye et al (2019), this adopted set of diffusion parameters gives rise to early TDU episodes and s-process enrichments in stars with masses as low as 1 M and compatible with observations.…”
Section: Models Of S-and I-processes In Low-mass Agb Starssupporting
confidence: 83%
“…We follow Eq. (9) of Goriely & Siess (2018) and use the same diffusive mixing parameters in our simulations as in Shetye et al (2019), i.e. f over = 0.14, D min = 10 7 cm 2 s −1 , and p = 1/2, where f over controls the extent of the mixing, D min is the value of the diffusion coefficient at the innermost boundary of the diffusive region, and p is an additional free parameter describing the shape of the diffusion profile.…”
Section: Models Of S-and I-processes In Low-mass Agb Starsmentioning
confidence: 99%
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“…First, if an appropriate statistics of bitrinsic stars were available, this would put interesting constraints on binary-synthesis evolution models, because the number of bitrinsic star depends, among other things, on the radius evolution during the RGB and AGB phases, which will determine whether/when a Roche-lobe overflow will occur, causing the disappearance of systems that would have become bitrinsic objects (Escorza et al 2020). A second constraint concerns the component masses: in order to exhibit s-process overabundances at their surface, AGB stars must have an initial mass larger than 1 M (as recently shown by Shetye et al 2019) and smaller than 4 − 5 M , above which the radiative s-process production is significantly reduced (Goriely & Siess 2004). Therefore, in the case of bitrinsic systems, both the primary and secondary components should satisfy this condition (along with M 1 > M 2 ).…”
Section: Discussionmentioning
confidence: 99%
“…The following sections present the detailed analysis of these stars. The analysis of the remaining of this sample is presented elsewhere (Shetye et al 2018(Shetye et al , 2019 and in a forthcoming paper (Shetye et al, in prep. ).…”
Section: Searching For Bitrinsic S Starsmentioning
confidence: 99%