EDGE: Dark matter core creation depends on the timing of star formation
Abstract
We study feedback-driven cold dark matter core creation in the EDGE suite of radiation-hydrodynamical dwarf galaxy simulations. Understanding this process is crucial when using observed dwarf galaxies to constrain the particle nature of dark matter. While previous studies have shown the stellar-mass to halo-mass ratio (M / M200) determines the extent of core creation, we find that in low-mass dwarfs there is a crucial additional effect, namely the timing of star formation relative to reionisation. Sustained post-reionisation star formation decreases central dark matter density through potential fluctuations; conversely, pre-reionisation star formation is too short-lived to have such an effect. In fact, large stellar masses accrued prior to reionisation are a strong indicator of early collapse, and therefore indicative of an increased central dark matter density. We parameterise this differentiated effect by considering M,post/M,pre, where the numerator and denominator represent the amount of star formation after and before z6.5, respectively. Our study covers the halo mass range 109 < M200 < 1010 M (stellar masses between 104 < M < 108 M), spanning both ultra-faint and classical dwarfs. In this regime, M,post/M,pre correlates almost perfectly with the central dark matter density at z=0, even when including simulations with a substantially different variant of feedback and cooling. We provide fitting formulae to describe the newfound dependence.
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