A complete effective field theory for dark matter

TL;DR

This paper develops a comprehensive effective field theory framework for describing interactions between the Standard Model and various dark matter candidates, including detailed operator bases and phenomenological applications.

Contribution

It introduces the most general gauge-invariant operator basis up to dimension six for electroweak multiplet dark matter, including hypercharged candidates, and demonstrates its use through phenomenological examples.

Findings

Constraints on Wilson coefficients from experimental data

Operators can dominate over gauge interactions in some cases

New parameter space windows opened by operator interplay

Abstract

We present an effective field theory describing the relevant interactions of the Standard Model with an electrically neutral particle that can account for the dark matter in the Universe. The possible mediators of these interactions are assumed to be heavy. The dark matter candidates that we consider have spin 0, 1/2 or 1, belong to an electroweak multiplet with arbitrary isospin and hypercharge and their stability at cosmological scales is guaranteed by imposing a $\mathbb{Z}_2$ symmetry. We present the most general framework for describing the interaction of the dark matter with standard particles, and construct a general non-redundant basis of the gauge-invariant operators up to dimension six. The basis includes multiplets with non-vanishing hypercharge, which can also be viable DM candidates. We give two examples illustrating the phenomenological use of such a general effective framework. First, we consider the case of a scalar singlet, provide convenient semi-analytical expressions for the relevant dark matter observables, use present experimental data to set constraints on the Wilson coefficients of the operators, and show how the interplay of different operators can open new allowed windows in the parameter space of the model. Then we study the case of a lepton isodoublet, which involves co-annihilation processes, and we discuss the impact of the operators on the particle mass splitting and direct detection cross sections. These examples highlight the importance of the contribution of the various non-renormalizable operators, which can even dominate over the gauge interactions in certain cases.