Dark Matter in Split SUSY with Intermediate Higgses

TL;DR

This paper explores a split SUSY scenario with intermediate Higgses, analyzing parameter space constraints from collider, dark matter, and gamma-ray data, and discusses implications for future direct detection experiments.

Contribution

It provides a comprehensive survey of MSSM parameter space with two scales, identifying regions consistent with current constraints and dark matter relic abundance, highlighting potential for future detection.

Findings

Viable dark matter regions with correct relic abundance identified.

Parameter space can be further constrained by upcoming direct detection experiments.

Surviving regions involve coannihilation and funnel mechanisms.

Abstract

The searches for heavy Higgs bosons and supersymmetric (SUSY) particles at the LHC have left the minimal supersymmetric standard model (MSSM) with an unusual spectrum of SUSY particles, namely, all squarks are beyond a few TeV while the Higgs bosons other than the one observed at 125 GeV could be relatively light. In light of this, we study a scenario characterized by two scales: the SUSY breaking scale or the squark-mass scale $(M_S)$ and the heavy Higgs-boson mass scale $(M_A)$.We perform a survey of the MSSM parameter space with $M_S < 10^{10}$ GeV and $M_A < 10^4$ GeV such that the lightest Higgs boson mass is within the range of the observed Higgs boson as well as satisfying a number of constraints. The set of constraints include the invisible decay width of the $Z$ boson and that of the Higgs boson, the chargino-mass limit, dark matter relic abundance from Planck, the spin-independent cross section of direct detection by LUX, and gamma-ray flux from dwarf spheroidal galaxies and gamma-ray line constraints measured by Fermi LAT. Survived regions of parameter space feature the dark matter with correct relic abundance, which is achieved through either coannihilation with charginos, $A/H$ funnels, or both. We show that future measurements, e.g., XENON1T and LZ, of spin-independent cross sections can further squeeze the parameter space.