Self-interacting dark matter

In astrophysics and particle physics, self-interacting dark matter (SIDM) is an alternative class of dark matter particles which have strong interactions, in contrast to the standard cold dark matter model (CDM). SIDM was postulated in 2000 as a solution to the core-cusp  problem. In the simplest models of DM self-interactions, a Yukawa-type potential and a force carrier φ mediates between two dark matter particles. On galactic scales, DM self-interaction leads to energy and momentum exchange between DM particles. Over cosmological time scales this results in isothermal cores in the central region of dark matter haloes.

If the self-interacting dark matter is in hydrostatic equilibrium, its pressure and density follow:
 * $$\nabla P_\chi/\rho_\chi = \nabla \Phi_{\rm tot} = \nabla (\Phi_\chi + \Phi_b)$$

where $$\Phi_{\chi}$$ and $$\Phi_{b}$$ are the gravitational potential of the dark matter and a baryon respectively. The equation naturally correlates the dark matter distribution to that of the baryonic matter distribution. With this correlation, the self-interacting dark matter can explain phenomena such as the Tully–Fisher relation.

Self-interacting dark matter has also been postulated as an explanation for the DAMA annual modulation signal. Moreover, it is shown that it can serve the seed of supermassive black holes at high redshift. SIDM may have originated in a so-called "Dark Big Bang".