Abstract
MSSM4G models, in which the minimal supersymmetric standard model is extended to include vector-like copies of standard model particles, are promising possibilities for weak-scale supersymmetry. In particular, two models, called QUE and QDEE, realize the major virtues of supersymmetry (naturalness consistent with the 125 GeV Higgs boson, gauge coupling unification, and thermal relic neutralino dark matter) without the need for fine-tuned relations between particle masses. We determine the implications of these models for dark matter and collider searches. The QUE and QDEE models revive the possibility of heavy Bino dark matter with mass in the range 300-700 GeV, which is not usually considered. Dark matter direct detection cross sections are typically below current limits, but are naturally expected above the neutrino floor and may be seen at next-generation experiments. Indirect detection prospects are bright at the Cherenkov Telescope Array, provided the 4th-generation leptons have mass above 350 GeV or decay to taus. In a completely complementary way, discovery prospects at the LHC are dim if the 4th-generation leptons are heavy or decay to taus, but are bright for 4th-generation leptons with masses below 350 GeV that decay either to electrons or to muons. We conclude that the combined set of direct detection, CTA, and LHC experiments will discover or exclude these MSSM4G models in the coming few years, assuming the Milky Way has an Einasto dark matter profile.
Highlights
IntroductionWeak-scale supersymmetry (SUSY) has the potential to solve the gauge hierarchy problem, accommodate grand unification, and explain dark matter in the form of a thermal relic neutralino
Weak-scale supersymmetry (SUSY) has the potential to solve the gauge hierarchy problem, accommodate grand unification, and explain dark matter in the form of a thermal relic neutralino. This potential has been sullied a bit by the lack of superpartners at the LHC and the measured Higgs mass of 125 GeV, which is higher than typically expected in the minimal supersymmetric standard model (MSSM) with sub-TeV superpartners
We examine the prospects for detecting these decays through charged particles, neutrinos, and gamma rays, and find promising prospects for future gamma-ray experiments, such as the Cherenkov Telescope Array (CTA), when the 4th-generation leptons are heavy or when they decay to taus
Summary
Weak-scale supersymmetry (SUSY) has the potential to solve the gauge hierarchy problem, accommodate grand unification, and explain dark matter in the form of a thermal relic neutralino This potential has been sullied a bit by the lack of superpartners at the LHC and the measured Higgs mass of 125 GeV, which is higher than typically expected in the minimal supersymmetric standard model (MSSM) with sub-TeV superpartners. [6], the annihilation process to 4th- (and 5th-) generation isosinglet charged leptons, BB → τ4+,5τ4−,5, is remarkably efficient, because it is enhanced by the large hypercharge factor (Yτ4,5)4 = 16 and is not chirality-suppressed by small fermion masses As a result, this process may single-handedly dominate the combined effect of tens of MSSM annihilation channels, reviving the viability of 300–700 GeV Bino dark matter, which, barring coannihilation, overcloses the Universe in the MSSM. Each category is divided into several signal regions (SRs) as follows:
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