Double-Disk Dark Matter

TL;DR

This paper explores a complex dark matter model called Double-Disk Dark Matter, which can form a disk within galaxies, leading to observable signals and new physics insights beyond the traditional cold, collisionless dark matter paradigm.

Contribution

It introduces the concept of Partially Interacting Dark Matter with a focus on the Double-Disk Dark Matter scenario, proposing a model where dark matter can cool and form a disk, with potential observable consequences.

Findings

Dark matter can form a disk within galaxies due to self-interactions.

Enhanced indirect detection signals could arise from dark matter density in the galactic plane.

Potential explanation for the 130 GeV Fermi line signal.

Abstract

Based on observational constraints on large scale structure and halo structure, dark matter is generally taken to be cold and essentially collisionless. On the other hand, given the large number of particles and forces in the visible world, a more complex dark sector could be a reasonable or even likely possibility. This hypothesis leads to testable consequences, perhaps portending the discovery of a rich hidden world neighboring our own. We consider a scenario that readily satisfies current bounds that we call Partially Interacting Dark Matter (PIDM). This scenario contains self-interacting dark matter, but it is not the dominant component. Even if PIDM contains only a fraction of the net dark matter density, comparable to the baryonic fraction, the subdominant component's interactions can lead to interesting and potentially observable consequences. Our primary focus will be the special case of Double-Disk Dark Matter (DDDM), in which self-interactions allow the dark matter to lose enough energy to lead to dynamics similar to those in the baryonic sector. We explore a simple model in which DDDM can cool efficiently and form a disk within galaxies, and we evaluate some of the possible observational signatures. The most prominent signal of such a scenario could be an enhanced indirect detection signature with a distinctive spatial distribution. Even though subdominant, the enhanced density at the center of the galaxy and possibly throughout the plane of the galaxy can lead to large boost factors, and could even explain a signature as large as the 130 GeV Fermi line. Such scenarios also predict additional dark radiation degrees of freedom that could soon be detectable and would influence the interpretation of future data, such as that from Planck and from the Gaia satellite. We consider this to be the first step toward exploring a rich array of new possibilities for dark matter dynamics.