We use high-resolution (≈10 pc), zoom-in simulations of a typical (stellar mass ⁠) Lyman Break Galaxy (LBG) at z ≃ 6 to investigate the stellar populations of its six dwarf galaxy satellites, whose stellar [gas] masses are in the range log (M⋆/M⊙) ≃ 6−9 [log (Mgas/M⊙) ≃ 4.3−7.75]. The properties and evolution of satellites show no dependence on the distance from the central massive LBG (<11.5 kpc). Instead, their star formation and chemical enrichment histories are tightly connected to their stellar (and sub-halo) mass. High-mass dwarf galaxies (⁠M⋆≳ 5 x 10⁸⁠M⊙) experience a long history of star formation, characterized by many merger events. Lower mass systems go through a series of short star formation episodes, with no signs of mergers; their star formation activity starts relatively late (z ≈ 7), and it is rapidly quenched by internal stellar feedback. In spite of the different evolutionary patterns, all satellites show a spherical morphology, with ancient and more metal-poor stars located towards the inner regions. All six dwarf satellites experienced high star formation rate (⁠> 5 M⊙ yr ⁻¹⁠) bursts, which can be detected by James Webb Space Telescope while targeting high-z LBGs.

The stellar populations of high-redshift dwarf galaxies

S Salvadori;A Pallottini;A Ferrara
2020

Abstract

We use high-resolution (≈10 pc), zoom-in simulations of a typical (stellar mass ⁠) Lyman Break Galaxy (LBG) at z ≃ 6 to investigate the stellar populations of its six dwarf galaxy satellites, whose stellar [gas] masses are in the range log (M⋆/M⊙) ≃ 6−9 [log (Mgas/M⊙) ≃ 4.3−7.75]. The properties and evolution of satellites show no dependence on the distance from the central massive LBG (<11.5 kpc). Instead, their star formation and chemical enrichment histories are tightly connected to their stellar (and sub-halo) mass. High-mass dwarf galaxies (⁠M⋆≳ 5 x 10⁸⁠M⊙) experience a long history of star formation, characterized by many merger events. Lower mass systems go through a series of short star formation episodes, with no signs of mergers; their star formation activity starts relatively late (z ≈ 7), and it is rapidly quenched by internal stellar feedback. In spite of the different evolutionary patterns, all satellites show a spherical morphology, with ancient and more metal-poor stars located towards the inner regions. All six dwarf satellites experienced high star formation rate (⁠> 5 M⊙ yr ⁻¹⁠) bursts, which can be detected by James Webb Space Telescope while targeting high-z LBGs.
2020
Settore FIS/05 - Astronomia e Astrofisica
galaxies: dwarf; galaxies: evolution; galaxies: formation; galaxies: high-redshift; cosmology: theory
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11384/89444
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