Mixing Uncertainties in Low-Metallicity AGB Stars: The Impact on Stellar Structure and Nucleosynthesis

Battino, U.; Lederer-Woods, C.; Cseh, B.; Denissenkov, Pavel A.; Herwig, Falk

doi:10.3390/universe7020025

Cited by 9 publications

(14 citation statements)

References 52 publications

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“…Nonetheless, we expect a non-trivial mass-metallicity dependence of the mixing triggered by magnetic buoyancy (as for other type of mixing, see e.g. Joyce & Chaboyer 2018;Battino et al 2021). In particular, the toroidal field strength is determined by the differential rotation profile established in the He-intershell and which amplifies the magnetic field via dynamo action (see Section 4).…”

Section: Stellar Modelsmentioning

confidence: 95%

Magnetic-buoyancy-induced mixing in AGB Stars: fluorine nucleosynthesis at different metallicities

Vescovi,

Cristallo,

Palmerini

et al. 2021

Preprint

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Asymptotic giant branch (AGB) stars are considered to be among the most significant contributors to the fluorine budget in our Galaxy. While at close-to-solar metallicity observations and theory agree, at lower metallicities stellar models overestimate the fluorine production with respect to heavy elements. We present 19 F nucleosynthesis results for a set of AGB models with different masses and metallicities in which magnetic buoyancy acts as the driving process for the formation of the 13 C neutron source (the so-called 13 C pocket). We find that 19 F is mainly produced as a result of nucleosynthesis involving secondary 14 N during convective thermal pulses, with a negligible contribution from the 14 N present in the 13 C pocket region. A large 19 F production is thus prevented, resulting in lower fluorine surface abundances. As a consequence, AGB stellar models with magnetic-buoyancy-induced mixing at the base of the convective envelope well agree with available fluorine spectroscopic measurements at both low and close-to-solar metallicity.

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Section: Stellar Modelsmentioning

confidence: 95%

Magnetic-buoyancy-induced mixing in AGB Stars: fluorine nucleosynthesis at different metallicities

Vescovi,

Cristallo,

Palmerini

et al. 2021

Preprint

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“…Vescovi et al (2020) found that most of the heavy-element isotope ratios measured in presolar SiC grains from AGB stars are consistently explained by stellar AGB models computed with a unique choice for the toroidal field strength and the initial buoyant velocity, namely B ϕ = 5×10 4 G and u p = 5×10 −5 cm s −1 . Nonetheless, we expect a nontrivial mass-metallicity dependence of the mixing triggered by magnetic buoyancy (as for other type of mixing; see, e.g., Joyce & Chaboyer 2018;Battino et al 2021). In particular, the toroidal field strength is determined by the differential rotation profile established in the He-intershell that amplifies the magnetic field through dynamo action (see Sect.…”

Section: Stellar Modelsmentioning

confidence: 95%

Magnetic-buoyancy-induced mixing in AGB stars: Fluorine nucleosynthesis at different metallicities

Vescovi

Cristallo

Palmerini

et al. 2021

A&A

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Asymptotic giant branch (AGB) stars are considered to be among the most significant contributors to the fluorine budget in our Galaxy. While observations and theory agree at close-to-solar metallicity, stellar models at lower metallicities overestimate the fluorine production with respect to that of heavy elements. We present 19F nucleosynthesis results for a set of AGB models with different masses and metallicities in which magnetic buoyancy acts as the driving process for the formation of the 13C neutron source (the so-called 13C pocket). We find that 19F is mainly produced as a result of nucleosynthesis involving secondary 14N during convective thermal pulses, with a negligible contribution from the 14N present in the 13C pocket region. A large 19F production is thus prevented, resulting in lower fluorine surface abundances. As a consequence, AGB stellar models with mixing induced by magnetic buoyancy at the base of the convective envelope agree well with available fluorine spectroscopic measurements at low and close-to-solar metallicity.

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“…The formation of an extended 13 C pocket induced by mixing processes can increase Ce production (e.g. Battino et al 2021) and may explain its overabundance in the young open clusters, as pointed out by Maiorca et al (2011).…”

Section: Discussionmentioning

confidence: 96%

Exploring the s-process history in the Galactic disk: Cerium abundances and gradients in Open Clusters from the OCCAM/APOGEE sample

Sales-Silva,

Daflon,

Cunha

et al. 2021

Preprint

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The APOGEE Open Cluster Chemical Abundances and Mapping (OCCAM) survey is used to probe the chemical evolution of the s-process element cerium in the Galactic disk. Cerium abundances were derived from measurements of Ce II lines in the APOGEE spectra using the Brussels Automatic Code for Characterizing High Accuracy Spectra (BACCHUS) in 218 stars belonging to 42 open clusters. Our results indicate that, in general, for Ages < 4 Gyr, younger open clusters have higher [Ce/Fe] and [Ce/α-element] ratios than older clusters. In addition, metallicity segregates open clusters in the [Ce/X]-Age plane (where X can be H, Fe, and the α-elements O, Mg, Si, or Ca). These metallicitydependant relations result in [Ce/Fe] and [Ce/α] ratios with age that are not universal clocks. Radial gradients of [Ce/H] and [Ce/Fe] ratios in open clusters, binned by age, were derived for the first time, with d[Ce/H]dR GC being negative, while d[Ce/Fe]/dR GC is positive. [Ce/H] and [Ce/Fe] gradients are approximately constant over time, with the [Ce/Fe] gradient becoming slightly steeper, changing by ∼+0.009 dex-kpc −1 -Gyr −1 . Both the [Ce/H] and [Ce/Fe] gradients are shifted to lower values of

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Mixing Uncertainties in Low-Metallicity AGB Stars: The Impact on Stellar Structure and Nucleosynthesis

Cited by 9 publications

References 52 publications

Magnetic-buoyancy-induced mixing in AGB Stars: fluorine nucleosynthesis at different metallicities

Magnetic-buoyancy-induced mixing in AGB Stars: fluorine nucleosynthesis at different metallicities

Magnetic-buoyancy-induced mixing in AGB stars: Fluorine nucleosynthesis at different metallicities

Exploring the s-process history in the Galactic disk: Cerium abundances and gradients in Open Clusters from the OCCAM/APOGEE sample

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