Prospects for dark matter searches in the pMSSM

TL;DR

This paper assesses the potential of the Cherenkov Telescope Array (CTA) to detect neutralino dark matter within the pMSSM, highlighting CTA's ability to exclude large parameter regions, especially for higgsino-like neutralinos around 1 TeV.

Contribution

It provides a detailed sensitivity analysis of CTA for dark matter detection in the pMSSM, focusing on realistic halo profiles and comparing with other detection methods.

Findings

CTA can exclude most of the ~1 TeV higgsino region with 500 hours of observation.

CTA is more sensitive than current direct detection experiments for certain parameter regions.

Many points beyond CTA sensitivity are accessible to 1-tonne detectors and colliders.

Abstract

We investigate the prospects for detection of neutralino dark matter in the 19-parameter phenomenological MSSM (pMSSM). We explore very wide ranges of the pMSSM parameters but pay particular attention to the higgsino-like neutralino at the ~ 1 TeV scale, which has been shown to be a well motivated solution in many constrained supersymmetric models, as well as to a wino-dominated solution with the mass in the range of 2-3 TeV. After summarising the present bounds on the parameter space from direct and indirect detection experiments, we focus on prospects for detection of the Cherenkov Telescope Array (CTA). To this end, we derive a realistic assessment of the sensitivity of CTA to photon fluxes from dark matter annihilation by means of a binned likelihood analysis for the Einasto and Navarro-Frenk-White halo profiles. We use the most up to date instrument response functions and background simulation model provided by the CTA Collaboration. We find that, with 500 hours of observation, under the Einasto profile CTA is bound to exclude at the 95% C.L. almost all of the ~ 1 TeV higgsino region of the pMSSM, effectively closing the window for heavy supersymmetric dark matter in many realistic models. CTA will be able to probe the vast majority of cases corresponding to a spin-independent scattering cross section below the reach of 1-tonne underground detector searches for dark matter, in fact even well below the irreducible neutrino background for direct detection. On the other hand, many points lying beyond the sensitivity of CTA will be within the reach of 1-tonne detectors, and some within collider reach. Altogether, CTA will provide a highly sensitive way of searching for dark matter that will be partially overlapping and partially complementary with 1-tonne detector and collider searches, thus being instrumental to effectively explore the nearly full parameter space of the pMSSM.