Neutron Star Mergers Might Not Be the Only Source of r-process Elements in the Milky Way

Côté, Benoît; Eichler, Marius; Arcones, Almudena; Hansen, C. J.; Simonetti, Paolo; Frebel, Anna; Fryer, Chris L.; Pignatari, M.; Reichert, Moritz; Belczyński, Krzysztof; Matteuccí, F.

doi:10.3847/1538-4357/ab10db

Cited by 220 publications

(203 citation statements)

References 279 publications

(433 reference statements)

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“…However, it has been reported that the evolutionary path of [Eu/Fe] predicted by NSMs is incompatible with the observed trend of disk stars due to a delayed r-process enrichment (Hotokezaka et al 2018). Thus, some authors claim the necessity of r-process-element contributions from some specific and rare core-collapse supernovae (CCSNe) that are capable of enriching gas much faster than NSMs, such as magneto-rotational SNe (Côté et al 2019) or collapsars (Siegel et al 2019). Similarly, stellar abundances of halo stars demand a fast enrichment of r-process (e.g., Mathews & Cowan 1990;Argast et al 2004).…”

Section: Introductionmentioning

confidence: 99%

“…In the end, the revealed feature suggest a large difference in [r-process/Fe] between metal-poor and metal-rich disk stars, which challenges the enrichment of Eu by NSMs. That's because r-process enrichment with the plausible DTD spanning over Gyrs for NSMs predicts only a small gradient in [Eu/Fe] with respect to [Fe/H] between the two endpoints of chemical evolution, compared to the case with fast r-process enrichment by CCSNe (Hotokezaka et al 2018;Côté et al 2019;Siegel et al 2019).…”

Section: Introductionmentioning

confidence: 99%

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Galactic r-process Abundance Feature Shaped by Radial Migration

Tsujimoto

Baba

2019

ApJ

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Growing interests in the chemical feature of r-process elements among nearby disk stars represented by the [Eu/Fe] vs. [Fe/H] diagram have sprouted since it can assess the origin of r-process elements through the comparison with theoretical models, including a test as to if neutron star mergers can be the major site of r-process nucleosynthesis. On the other hand, recent studies reveal that local chemistry is strongly coupled with the dynamics of Galactic disk, which predicts that stars radially move on the disk where the observed elemental feature is different at various Galactocentric distances.Here, we show that radial migration of stars across the Galactic disk plays a crucial role in shaping the r-process abundance feature in the solar vicinity. In this proposed scenario, we highlight the importance of migration from the outer disk where [r-process/Fe] of some old stars is predicted to be enhanced to the level beyond the expectation from the observed Galactic Fe and Eu radial gradient, which results in a large span of [r-process/Fe] among nearby disk stars. The variation in the [r-process/Fe] ratio seen across the Galactic disk as well as in dwarf galaxies may be an outcome of different stellar initial mass functions which change the occurrence frequency between supernovae leaving behind neutron stars and ones ending with black holes. Here we propose that enhancement in [Eu/Fe] is attributed to the initial mass function lacking high-mass stars such as > ∼ 25M ⊙ in the scheme for which neutron star mergers are a major source of r-process elements.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Galactic r-process Abundance Feature Shaped by Radial Migration

Tsujimoto

Baba

2019

ApJ

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“…An additional important source of uncertainty comes from the nuclear inputs adopted to calculate the r-process nucleosynthesis, the most important ones being nuclear masses, β-decay rates and nuclear fission models (Eichler et al 2015;Thielemann et al 2017). Finally, the observed evolution of the r-elements in the Galaxy is hard (albeit not impossible) to conciliate with our current understanding of the occurrence rate of NSMs, regarding both the early (halo) and the late (disk) phases of the Milky Way (Tsujimoto & Shigeyama 2014;Ishimaru et al 2015;Ojima et al 2018;Côté et al 2018;Hotokezaka et al 2018;Côté et al 2018;Guiglion et al 2018;Wehmeyer et al 2019;Siegel et al 2019;Haynes & Kobayashi 2019;Côté et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Chemical evolution with rotating massive star yields II. A new assessment of the solar s- and r- process components

Prantzos

Abia

Cristallo

et al. 2019

Monthly Notices of the Royal Astronomical Society

123

151

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The decomposition of the Solar system abundances of heavy isotopes into their sand r-components plays a key role in our understanding of the corresponding nuclear processes and the physics and evolution of their astrophysical sites. We present a new method for determining the s-and r-components of the Solar system abundances, fully consistent with our current understanding of stellar nucleosynthesis and galactic chemical evolution. The method is based on a study of the evolution of the solar neighborhood with a state-of-the-art 1-zone model, using recent yields of low and intermediate mass stars as well as of massive rotating stars. We compare our results with previous studies and we provide tables with the isotopic and elemental contributions of the s-and r-processes to the Solar system composition.

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“…At higher metallicity, [Fe/H] > −1, the abundances of the r-process element 1 Eu have been proven impossible to reproduce with NSMs as the only r-process source when physically motivated time delay distributions are adopted (e.g. Shen et al 2015;van de Voort et al 2015;Komiya & Shigeyama 2016;Côté et al 2019;Hotokezaka et al 2018;Simonetti et al 2019). On the other hand, if short timescales of NSMs are assumed ( 10 8 yr), the abundance trend of the Milky Way disks can be readily explained (e.g.…”

Section: Introductionmentioning

confidence: 99%

Evidence for ≳4 Gyr timescales of neutron star mergers from Galactic archaeology

Skúladóttir

Salvadori

2020

A&A

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The nucleosynthetic site of the rapid (r) neutron-capture process is currently being debated. The direct detection of the neutron star merger GW170817, through gravitational waves and electromagnetic radiation, has confirmed such events as important sources of the r-process elements. However, chemical evolution models are not able to reproduce the observed chemical abundances in the Milky Way when neutron star mergers are assumed to be the only r-process site and realistic time distributions of such events are taken into account. Now for the first time, we combine all the available observational evidence of the Milky Way and its dwarf galaxy satellites to show that the data can only be explained if there are (at least) two distinct r-process sites: a quick source with timescales comparable to core-collapse supernovae, t quick 10 8 yr, and a delayed source with characteristic timescales t delayed 4 Gyr. The delayed r-process source most probably originates in neutron star mergers, as the timescale fits well with that estimated for GW170817. Given the short timescales of the quick source, it is likely associated with massive stars, though a specific fast-track channel for compact object mergers cannot be excluded at this point. Our approach demonstrates that only by looking at all the available data will we be able to solve the puzzle that is the r-process.

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Neutron Star Mergers Might Not Be the Only Source of r-process Elements in the Milky Way

Cited by 220 publications

References 279 publications

Galactic r-process Abundance Feature Shaped by Radial Migration

Galactic r-process Abundance Feature Shaped by Radial Migration

Chemical evolution with rotating massive star yields II. A new assessment of the solar s- and r- process components

Evidence for ≳4 Gyr timescales of neutron star mergers from Galactic archaeology

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