Searching for feebly interacting dark matter at colliders and beam-dump experiments

TL;DR

This paper explores the detection of feebly interacting dark matter particles, called FIMPs, through long-lived particle signatures at colliders and beam-dump experiments, highlighting new production mechanisms and search strategies.

Contribution

It introduces a classification of FIMP models and analyzes potential future searches for long-lived particles in collider and beam-dump experiments.

Findings

FIMP models can produce detectable long-lived particles.

Existing searches constrain some FIMP parameter spaces.

Future experiments could probe additional FIMP scenarios.

Abstract

Despite the compelling amount of evidence for the existence of dark matter, its exact nature is still one of the main open questions in modern physics. A great experimental effort has been performed to probe one of the most popular dark matter candidates, the Weakly Interacting Massive Particle or WIMP, however, there has not been any conclusive detection yet. Hence, these searches place strong constraints on the WIMP paradigm. The community has therefore started to consider alternatives who are able to evade the strong experimental constraints. Such a candidate that has gained a lot of attention in the recent years is the Feebly Interacting Massive Particle or FIMP. Unlike the WIMP, the FIMP has very feeble interactions. It is therefore unable to reach a state of equilibrium which is needed to be produced trough freeze-out. Despite these feeble interactions, there is still a variety of mechanisms able to produce the observed amount of dark matter in our universe. In this work, a selection of these mechanisms, such as freeze-in or conversion driven freeze-out, are discussed in detail. Since these FIMPs are so feebly interacting with standard model particles, it is difficult to probe these particles through conventional direct and indirect detection searches. In contrast, the feeble couplings give rise to long-lived particles coupling to the DM, which can hence be smoking gun signatures for FIMPs. This thesis will therefore focus on searches for long-lived particles, both at hadron colliders and beam-dump experiments. In order to do so, a classification of FIMP models has been put forward within the context of this PhD, in which potential production mechanisms are identified in order to define a viable parameter space. Within this framework, both existing and potential future searches for long-lived particles are discussed and applied to a subset of the proposed classification.