Bibcode
Haas, Marcel R.; Schaye, Joop; Booth, C. M.; Dalla Vecchia, C.; Springel, Volker; Theuns, Tom; Wiersma, Robert P. C.
Referencia bibliográfica
Monthly Notices of the Royal Astronomical Society, Volume 435, Issue 4, p.2931-2954
Fecha de publicación:
11
2013
Número de citas
72
Número de citas referidas
71
Descripción
We use hydrodynamical simulations from the OverWhelmingly Large
Simulations (OWLS) project to investigate the dependence of the physical
properties of galaxy populations at redshift 2 on metal-line cooling and
feedback from star formation and active galactic nuclei (AGN). We find
that if the sub-grid feedback from star formation is implemented
kinetically, the feedback is only efficient if the initial wind velocity
exceeds a critical value. This critical velocity increases with galaxy
mass and also if metal-line cooling is included. This suggests that
radiative losses quench the winds if their initial velocity is too low.
If the feedback is efficient, then the star formation rate is inversely
proportional to the amount of energy injected per unit stellar mass
formed (which is proportional to the initial mass loading for a fixed
wind velocity). This can be understood if the star formation is
self-regulating, i.e. if the star formation rate (and thus the gas
fraction) increases until the outflow rate balances the inflow rate.
Feedback from AGN is efficient at high masses, while increasing the
initial wind velocity with gas pressure or halo mass allows one to
generate galaxy-wide outflows at all masses. Matching the observed
galaxy mass function requires efficient feedback. In particular, the
predicted faint-end slope is too steep unless we resort to highly mass
loaded winds for low-mass objects. Such efficient feedback from low-mass
galaxies (M* ≪ 1010 M⊙) also
reduces the discrepancy with the observed specific star formation rates,
which are higher than predicted unless the feedback transitions from
highly efficient to inefficient just below M* ˜ 5
× 109 M⊙.