Supernova-driven Mechanism of Cusp-core Transformation: an Appraisal

We present and test an effective model for N-body simulations that aims at mimicking the impact of supernova (SN) feedback on the dark matter (DM) distribution of isolated halos hosting dwarf galaxies. Although the model is physically decoupled from the cosmological history of both the DM halo and the dwarf galaxy, it allows us to study the impact of different macroscopic parameters such as galaxy concentration, feedback energy, and energy injection time in the process of SN-driven core formation in a physically clear way. Using our effective model in a suite of N-body simulations of an isolated halo with different SN feedback parameters, we find that whether or not a DM core forms is determined by the total amount of SN feedback energy that is transferred to the DM particles. At a fixed injected energy, transfer of energy to the DM is more efficient the faster the energy is injected and the more compact the galaxy is, leading to an increased size of the formed DM core as a result. Analyzing the orbital evolution of kinematic tracers, we demonstrate that a core forms through SN feedback only if the energy injection is impulsive relative to the dynamical timescale of particles in the inner halo. However, there is no fundamental link between the total amount of injected energy and the injection rate. Consequently, the presence of signatures of impulsive changes of the gravitational potential is not a sufficient condition for dwarf-sized halos to have cored density profiles.

Automated summary

The study focuses on the impact of supernova feedback on the dark matter distribution of isolated halos hosting dwarf galaxies. It is found that the total amount of SN feedback energy transferred to dark matter particles determines whether a DM core forms. The efficiency of energy transfer to dark matter is higher when energy is injected faster and the galaxy is more compact, leading to an increased size of the formed DM core.