📝 SummarXiv

Abstract

We study the build-up and survival of angular momentum in the stellar disc using a statistical suite of cosmological simulations of Milky Way-mass galaxies. Our results show that stellar kinematics at $z=0$ rarely recover the true times of disc spin-up, due to the disruptive impact of massive radial merger events. The proto-disc (i.e. Aurora) and kicked-up disc stars (the Splash) become indistinguishable at low metallicities, and the local fraction of kicked-up disc stars remains $<20$ per cent even in the case of major mergers. In contrast, observations from Gaia and legacy surveys reveal that Galactic $\alpha$-rich populations as old as $\tau=13.5\,\rm{Gyr}$ show significant rotation, with median $\eta > 0.75$. This places strong constraints on the merger ratio between the proto-Milky Way and its last significant merger (Gaia-Sausage Enceladus, GSE), favouring values of $\lesssim 1:7$. We present the age-metallicity relation for the stellar halo and estimate the interaction epoch at $\tau_{\rm{spin\text{-}up}}\simeq\tau_{\rm{GSE}}\sim11\,\rm{Gyr}$. We note an abrupt dearth of halo and Splash stars after a lookback time of $10\,\rm{Gyr}$, marking the end of the merger interaction. Finally, we show that Globular Clusters in the metallicity range $-0.8<\rm{[Fe/H]}<-0.3$ align with a formation time of $\tau_{\rm{starburst}}\sim11\,\rm{Gyr}$, which we interpret as a signature of a starburst triggered by the first pericentric interaction of the GSE. This is remarkable corroboration between our GSE interaction and starburst times of $\tau_{\rm GSE}=\tau_{\rm starburst} \sim 11\,$Gyr.