NEFERTITI: Linking early galaxy formation to the assembly of the Milky Way

Abstract

We use a new implementation of the NEFERTITI galaxy formation model, coupled to 30 high-resolution Caterpillar dark-matter simulations of Milky Way (MW) analogues, to connect early galaxy formation with the MW's assembly down to z=0. Our locally-constrained model resolves minihaloes hosting the first PopIII stars and self-consistently tracks inhomogeneous ionization and chemical enrichment. PopIII star formation begins at z27, peaks at z10-15, and persists down to z5, producing PopIII systems with M*10-5×105\: M. The present-day descendants of PopIII stars span [Fe/H]<-9 to [Fe/H]≈-1, with the most metal-poor stars typically enriched by a few (1-4) low-energy supernova progenitors. Pair-instability supernova descendants more commonly form in massive haloes (M vir>108\: M), often externally enriched, reflecting the strong feedback and delayed recovery following energetic explosions. These early systems serve as building blocks for the present-day Galaxy's metal-poor component: although 90\% of the total stellar mass formed in situ, the accreted component dominates at [ Fe/H]<-1 and accounts for nearly all stars with [ Fe/H]<-3. This accreted population is largely built by a few (5) massive (M*>108\: M) destroyed dwarfs, but lower-mass systems become increasingly important at low metallicities, with ultra-faint and classical dSph analogues contributing 25\% at [ Fe/H]<-3. Our model simultaneously reproduces the properties of metal-poor MW stars and the JWST "Hebe" galaxy at z11, supporting its identification as a pure PopIII system. Ultimately, NEFERTITI is a key tool to interpret upcoming local and high-z observations linking the near- and far-field cosmology.