Scalar Dark Matter and Stability of Higgs Vacuum within a Minimal SO(10) GUT Model

Abstract

In this work, we delve to investigate a feasible range of dark matter (DM) masses within a non-supersymmetric SO(10) Grand Unified Theory (GUT) scalar dark matter model, in freeze-out scenario. This model includes a singlet scalar denoted as S and an inert doublet represented by φ. Being part of SO(10), the quantum numbers of DM particles are assigned and hence we know their nature. These fields are odd under a discrete Z2 matter parity (-1)3(B-L). The dark matter with mass 300 ≤ MDM ≤ 1000 GeV emerges as a mixture of the Z2-odd scalar singlet S and the neutral element of the doublet φ, both residing within a 16-dim scalar representation of SO(10). In this work we consider a real scalar S belonging to 16 of SO(10) as DM. We also investigate the one-loop vacuum stability through the solution of Renormalization Group Equations (RGEs) for the model's parameters. Subsequently, we scrutinize the model's predictions within the confines of contemporary theoretical and experimental restrictions. In addition to achieving vacuum stability in the SO(10) framework, the DM mass is found to lie in the previously unaddressed (theoretically) intermediate mass region of 300≤slant MDM ≤slant 1000 GeV which also adheres to many current phenomenological constraints, like recent direct experimental bounds from XENON1T, indirect detection bounds from Fermi-LAT experiment, Higgs invisible decay and Electroweak Precision Test. The stability of the electroweak vacuum is seen to be present up to the Planck scale. These model predictions possess the potential for future validation through dark matter search experiments, as they are testable in future DM search experiments, along with the added feature that the model is a part of an elegant grand unified theory.