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      <Title>Gaseous infall and star formation from redshift 2 to the Milky Way</Title>
      
      <Abstract>We propose to model magnetized gas as it flows into galaxy disks in Milky Way-like and redshift ~2 environments in order to understand the pc to kpc scale physics that control a crucial link in galaxy evolution: how do galaxies get the gas which sustains star formation over cosmic time? UV observations with the Cosmic Origins Spectrograph (COS) on HST have demonstrated that star-forming galaxies have baryonic halos much more massive than the galaxies themselves; these halos are most likely a link in the evolution of galaxies as cosmological filaments feed ongoing star formation in galactic disks. However, the galaxy formation simulations that support this hypothesis do not resolve the parsec-scale hydrodynamic processes which determine if and how the gas in the halo can reach the disk. To address this theoretical disconnect, we will conduct magnetohydrodynamic simulations in which these clouds fall under the galactic potential into a state-of-the-art simulation of the three-phase interstellar medium in the galactic disk.  We will leverage recent HST and radio observations of accreting clouds around the Milky Way to set the initial conditions of the gas, including magnetic fields and metallicity.  Our results will connect the HST metallicity measurements directly to the impact of gaseous galactic halos and infall on galaxy evolution and the star formation history of the Universe.</Abstract>
      
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         FirstName="Alex"
         MiddleInitial="S"
         LastName="Hill"
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         Institution="Haverford College"
         Country="USA"
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         FirstName="Desika"
         LastName="Narayanan"
         ESAMember="false"
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         UniqueID="9475"
         Institution="Haverford College"
         Country="USA"
         State="PA"
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         FirstName="Mordecai-Mark"
         LastName="Mac Low"
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         Institution="American Museum of Natural History"
         Country="USA"
         State="NY"
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         <ScientificCategory>ISM IN EXTERNAL GALAXIES</ScientificCategory>
         
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