Constraints on dark matter self-interaction from the internal density profiles of X-COP galaxy clusters

TL;DR

This study uses galaxy cluster observations and simulations to constrain dark matter self-interactions, finding that such interactions are limited to very low cross sections, supporting the cold dark matter model.

Contribution

It provides the first observational constraints on dark matter self-interaction cross sections from galaxy cluster density profiles.

Findings

Measured Einasto shape parameters consistent with cold dark matter predictions.

Derived upper limit on dark matter self-interaction cross section: < 0.19 cm^2/g.

Constraints suggest self-interactions are unlikely to solve small-scale structure problems.

Abstract

TThe fundamental properties of the postulated dark matter (DM) affect the internal structure of gravitationally-bound structures. In the cold dark matter paradigm, DM particles interact only via gravity. Their distribution is well represented by an Einasto profile with shape parameter $\alpha\approx0.18$, in the smallest dwarf galaxies or the most massive galaxy clusters alike. Conversely, if dark matter particles self-interact via additional forces, we expect the mass density profiles of DM halos to flatten in their central regions, thereby increasing the Einasto shape parameter. We measure the structural properties of the 12 massive X-COP galaxy clusters from observations of their hot gaseous atmosphere using the X-ray observatory XMM-Newton, and of the Sunyaev-Zeldovich effect using the Planck all-sky survey. After removing morphologically disturbed systems, we measure Einasto shape parameters with mean $\langle\alpha\rangle = 0.19 \pm 0.03$ and intrinsic scatter $\sigma_{\alpha}=0.06$, in close agreement with the prediction of the cold dark matter paradigm. We use cosmological hydrodynamical simulations of cluster formation with self-interacting DM (BAHAMAS-SIDM) to determine how the Einasto shape parameter depends on the self-interaction cross section. We use the fitted relation to turn our measurements of $\alpha$ into constraints on the self-interaction cross section, which imply $\sigma/m < 0.19$ cm$^2$/g (95% confidence level) at collision velocity $v_\mathrm{DM-DM}\sim1,000$ km/s. This is lower than the interaction cross-section required for dark matter self-interactions to solve the core-cusp problem in dwarf spheroidal galaxies, unless the cross section is a strong function of velocity.