Origins of Hidden Sector Dark Matter II: Collider Physics

TL;DR

This paper explores how collider experiments can identify the origin of hidden sector dark matter in supersymmetric theories by analyzing LOSP decay signatures and portal interactions at the LHC.

Contribution

It systematically studies LOSP candidates and portal interactions to determine how different dark matter production mechanisms can be distinguished at colliders.

Findings

Long-lived LOSPs produce displaced vertex signatures.

Charged or colored LOSPs are especially promising for detection.

Different DM production mechanisms correspond to specific LOSP decay patterns.

Abstract

We consider a broad class of supersymmetric theories in which dark matter (DM) is the lightest superpartner (LSP) of a hidden sector that couples very weakly to visible sector fields. Portal interactions connecting visible and hidden sectors mediate the decay of the lightest observable superpartner (LOSP) into the LSP, allowing the LHC to function as a spectacular probe of the origin of hidden sector DM. As shown in a companion paper, this general two-sector framework allows only for a handful of DM production mechanisms, each of which maps to a distinctive window in lifetimes and cross-sections for the LOSP. In the present work we perform a systematic collider study of LOSP candidates and portal interactions, and for each case evaluate the prospects for successfully reconstructing the origin of DM at the LHC. If, for instance, DM arises from Freeze-Out and Decay, this may be verified if the LOSP is a bino or right-handed slepton decaying to the LSP through a variety of portal interactions, and with an annihilation cross-section within a narrow range. On the other hand, the Freeze-In mechanism may be verified for a complimentary set of LOSP candidates, and within a narrow range of LOSP lifetimes. In all cases, the LOSP is relatively long-lived on collider time scales, leading to events with displaced vertices. Furthermore, scenarios with a charged or colored LOSP are particularly promising.