Real singlet scalar dark matter extension of the Georgi-Machacek model

TL;DR

This paper explores an extension of the Georgi-Machacek model with a singlet scalar dark matter candidate, analyzing its implications for dark matter detection and Higgs boson properties, and identifying regions consistent with current constraints.

Contribution

It introduces a singlet scalar dark matter extension to the Georgi-Machacek model and studies its phenomenological viability under relic density and detection constraints.

Findings

Singlet scalar masses below ~57 GeV are excluded by relic density and direct detection.

Higgs measurements currently do not significantly constrain the model.

Certain parameter regions evade future direct detection experiments for masses above 120 GeV.

Abstract

The Georgi-Machacek model extends the Standard Model Higgs sector with the addition of isospin-triplet scalar fields in such a way as to preserve the custodial symmetry. The presence of higher-isospin scalars contributing to electroweak symmetry breaking offers the interesting possibility that the couplings of the 125 GeV Higgs boson to both gluons and vector boson pairs could be larger than those of the Standard Model Higgs boson. Constraining this possibility using measurements of Higgs production and decay at the CERN Large Hadron Collider is notoriously problematic if a new, non-Standard Model decay mode of the 125 GeV Higgs boson is present. We study an implementation of this scenario in which the Georgi-Machacek model is extended by a real singlet scalar dark matter candidate, and require that the singlet scalar account for all the dark matter in the universe. The combination of the observed dark matter relic density and direct detection constraints exclude singlet scalar masses below about 57 GeV. Higgs measurements are not yet precise enough to be very sensitive to $h\rightarrow SS$ in the remaining allowed kinematic region, so that constraints from Higgs measurements are so far the same as in the GM model without a singlet scalar. We also find that, above the Higgs pole, a substantial region of parameter space yielding the correct dark matter relic density can escape the near-future direct detection experiments DEAP and XENON~1T for dark matter masses as low as 120 GeV and even have a direct detection cross section below the neutrino floor for $m_S\gtrsim 150$ GeV. This is in contrast to the singlet scalar dark matter extension of the Standard Model, for which these future experiments are expected to exclude dark matter masses above the Higgs pole up to the multi-TeV range.