Formation and Evolution of Self-Interacting Dark Matter Halos
Abstract
We study the formation and evolution of self-interacting dark matter (SIDM) halos. We find analytical, fully cosmological similarity solutions taking account of the collisional interaction of SIDM particles. This interaction results in a thermal conductivity that heats the halo core and flattens its density profile. These similarity solutions are relevant to galactic and cluster halo formation in the CDM model. We assume an initial mass profile dM/M M-eps, as in the familiar secondary infall model. If eps=1/6, SIDM halos will evolve self-similarly, with a cold, supersonic infall terminated by a strong accretion shock. Different solutions arise for different values of the collisionality parameter, Q= sigma rhob rs, where sigma is the scattering cross section, rhob is the cosmic mean density, and rs is the shock radius. For all these solutions, a flat-density, isothermal core is present which grows in size as a fixed fraction of rs. We find two different regimes for these solutions: 1) for Q ≤ Qth, the core density decreases and core size increases as Q increases; 2) for Q ≥ Qth, the core density increases and core size decreases as Q increases. Our similarity solutions are in agreement with previous N-body simulations of SIDM halos, which correspond to the low-Q regime, if Q=[8.4e-4 - 4.9e-2]Qth (low-Q), or sigma=[0.56-5.6]cm2/g. As Q=∞, our similarity solution aquires a central density cusp, in agreement with some simulation results which used an ordinary collisional fluid to approximate the effects of SIDM collisionality. When Q=[18.6-231]Qth or sigma=[1.2e4 - 2.71e4]cm2/g, for which we find flat-density cores comparable to those of the observationally acceptable low-Q solutions, has not previously been identified. Further study of this regime is warranted.
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