Vector Mediator coupling only to 1st generation quarks, Majorana Dark Matter

Jon Butterworth, David Grellscheid, Michael Krämer, Bjorn Sarrazin, David Yallup

This is the model discussed in the ‘white paper’ [92]. Some later results are also discussed in [90]. It is a simplified model with a dark matter Majorana fermion, \(\psi\), which interacts with the SM through a new vector particle, \(Z^\prime\). The couplings of the mediator \(Z^\prime\) to the dark matter \(\psi\) and to the SM are specified as

\[\begin{aligned} \label{eq:vector_mediator} {\cal L} \supset {{g_{\rm DM}}}\,\overline{\psi} \gamma_{\mu}\gamma_5 \psi\,Z'^{\mu} + {{g_{q}}}\sum_{q} \bar q \gamma_{\mu} q \,Z'^{\mu} \,,\end{aligned}\]

where the sum in the second term includes only the first generation SM quarks, \(q \in \{u,d\}\). The model has only four free parameters - two couplings and two masses: \(g_{\rm DM}\), \(g_{q}\), \(M_\psi \equiv {{M_{\rm DM}}}\), and \(M_{Z^{\prime}}\). The width of the mediator, \(\Gamma_{Z'}\), is determined by these four parameters.

Following Ref. [116] the mediator couples to dark matter and to the SM quarks through an axial-vector and vector current, respectively. An axial-vector coupling of the mediator to dark matter leads to spin-dependent dark matter-nucleon interactions and thus weaker bounds from direct dark matter searches. Such a coupling structure naturally arises for Majorana fermion dark matter.

To investigate the exclusion power of the particle-level measurements considered, we scanned a range in plausible mediator masses (\(M_{Z^{\prime}}\)) and dark matter masses (\(M_{\rm DM}\)) within this model for three choices of the coupling of the mediator to the SM (\(g_{q}\)). The results at the time are shown in the paper [92]. By now, however, most of the parameter plane is excluded for all of them except the “challenging” scenario, which (\({{g_{q}}}= 0.25, {{g_{\rm DM}}}= 1\):) is also a common benchmark choice for other studies of similar models, e.g. LPCC led studies (see Vector mediator, Dirac fermion DM ) and is the only one updated here. (Last updated Contur 1.0.x, Rivet 3.1.0, Herwig 7.2, 02/02/2020, using correlation information from the experimental measurements where available.)

../../_images/combinedHybrid-corr3.png

The rather odd shapes comes from the fact that different signatures and measurements affect different areas and they don’t quite overlap. At low \(M_{Z^{\prime}}\), vector-boson-plus-jet measurements have most sensitivity (see heatmap the CMS photon analyses [99] below left as an example). At low \(M_{\rm DM}\), the ATLAS missing-energy-plus-jet measurement [6] (again, see below, second left). At higher \(M_{\rm DM}\) and \(M_{Z^{\prime}}\), the dijet analyses have most impact (again, see below, right and second right, [137], [124], [3]).

NB the lowest mass point generated is \(M_{\rm Z^\prime}= 10\) GeV, so the limit does not really extend to zero. For a zoom on the low mass region in a similar model, see Vector mediator, Dirac fermion DM.

../../_images/CMS_7_GAMMAMesh.png ../../_images/ATLAS_13_METJETMesh.png ../../_images/CMS_8_JETSMesh.png ../../_images/ATLAS_13_JETSMesh.png

Heatmaps for photons, missing energy, 8 TeV and 13 TeV jets.

The model files are available in the DM_vector_mediator_UFO directory here