Discovery of an Extremely r-process-enhanced Thin-disk Star with [Eu/H] = +0.78

TL;DR

This paper reports the discovery of a rare, metal-rich, highly r-process-enhanced thin-disk star with unprecedented europium abundance, challenging existing notions about the environments of such stars.

Contribution

The study identifies and characterizes a highly r-process-enhanced star with unusually high metallicity and europium abundance, expanding knowledge of r-process element distribution in the Milky Way.

Findings

The star has [Eu/H] = +0.78, the highest measured among similar stars.

It is a thin-disk star with no association to known streams or dwarf galaxies.

The star's abundance pattern differs from typical metal-poor r-II stars.

Abstract

Highly r-process-enhanced stars are rare and usually metal-poor ([Fe/H] < - 1.0), and mainly populate the Milky Way halo and dwarf galaxies. This study presents the discovery of a relatively bright (V = 12.72), highly r-process-enhanced (r-II) star ([Eu/Fe] = +1.32, [Ba/Eu] = - 0.95), LAMOST J020632.21 + 494127.9. This star was selected from the Large Sky Area Multi-Object Fiber Spectroscopic Telescope (LAMOST) medium-resolution (R ~ 7500) spectroscopic survey; follow-up high-resolution (R ~ 25,000) observations were conducted with the High Optical Resolution Spectrograph (HORuS) installed on the Gran Telescopio Canarias (GTC). The stellar parameters (${T_{\rm eff}}$ = 4130 K, $\rm log\,g $ = 1.52, $ \rm[Fe/H] $ = $ - $0.54, $\xi$ = 1.80 $ \rm{km\,{s^{-1}}} $) have been inferred taking into account non-local thermodynamic equilibrium (NLTE) effects. The abundances of [Ce/Fe], [Pr/Fe], and [Nd/Fe] are +0.19, +0.65 and +0.64, respectively, relatively low compared to the Solar r-process pattern normalized to Eu. This star has a high metallicity ([Fe/H] = - 0.54) compared to most other highly r-process-enhanced stars, and has the highest measured abundance ratio of Eu to H ([Eu/H] = +0.78). It is classified as a thin-disk star based on its kinematics, and does not appear to belong to any known stream or dwarf galaxy.