The extended "stellar halo" of the Ursa Minor dwarf galaxy

Five stars in the extreme outskirts (from $\sim5$ to $\sim12$ elliptical half-light radii, r$_h$) of the Ursa Minor (UMi) dwarf galaxy have been identified as potential new members using a Bayesian algorithm applied to \textit{Gaia} EDR3 data. These targets were observed with the GRACES spectrograph, resulting in precise radial velocities and metallicities that confirm their association with UMi. For the brightest and outermost star (Target~1, at $\sim12$ r$_h$), the chemical abundances of $\alpha$- (Mg, Ca, Ti), odd-Z (Na, K, Sc), Fe-peak (Fe, Ni, Cr), and neutron-capture process (Ba) elements have also been determined. We also discuss data from the literature and from APOGEE DR17. We find the chemical patterns in UMi are consistent with a star formation history that includes yields from core collapse supernovae, asymptotic giant branch stars, and supernovae Ia. Evidence for a knee in the [$\alpha$/Fe] ratios near [Fe/H] $\sim-2.1$ indicates a low star formation efficiency similar to that in other dwarf galaxies. Given the distance of Target~1 from the centre of UMi (R$\sim$4.5 kpc), we show that UMi has a more extended structure than previously thought. This "stellar halo" around UMi could be a secondary feature resulting from tidal stripping after multiple orbits around the Galaxy, or maybe a primary UMi feature due to early hierarchical accretion activity or to strong gravitational fluctuations prompted by feedback in the early star formation phase. Also consistent with observations is a late-time merger-free scenario where outside-in star formation is accompanied by gradual supernovae Ia enrichment.