Abstract
In light of the recent discovery by the ATLAS and CMS experiments at the Large Hadron Collider (LHC) of a Higgs-like particle with a narrow mass range of 125–126 GeV, we perform an updated analysis on one of the popular scalar dark matter models, the Inert Higgs Doublet Model (IHDM). We take into account in our likelihood analysis of various experimental constraints, including recent relic density measurement, dark matter direct and indirect detection constraints as well as the latest collider constraints on the invisible decay width of the Higgs boson and monojet search at the LHC. It is shown that if the invisible decay of the standard model Higgs boson is open, LHC as well as direct detection experiments like LUX and XENON100 could put stringent limits on the Higgs boson couplings to dark matter. We find that the most favoured parameter space for IHDM corresponds to dark matter with a mass less than 100 GeV or so. In particular, the best-fit points are at the dark matter mass around 70 GeV where the invisible Higgs decay to dark matter is closed. Scalar dark matter in the higher mass range of 0.5–4 TeV is also explored in our study. Projected sensitivities for the future experiments of monojet at LHC-14, XENON1T and AMS-02 one year antiproton flux are shown to put further constraints on the existing parameter space of IHDM.
Highlights
The 7 TeV and 8 TeV run at the Large Hadron Collider (LHC) have revealed and confirmed the existence of a Higgs-like particle h in the standard model (SM) with mass in the narrow range of 125-126 GeV) mS ( (GeV) [1, 2]
We take into account in our likelihood analysis of various experimental constraints, including recent relic density measurement, dark matter direct and indirect detection constraints as well as the latest collider constraints on the invisible decay width of the Higgs boson and monojet search at the LHC
We find that the most favoured parameter space for Inert Higgs Doublet Model (IHDM) corresponds to dark matter with a mass less than 100 GeV or so
Summary
The 7 TeV and 8 TeV run at the Large Hadron Collider (LHC) have revealed and confirmed the existence of a Higgs-like particle h in the standard model (SM) with mass in the narrow range of 125-126 GeV [1, 2]. In addition to γ-rays, we include constraints from cosmic ray electrons/positrons from AMS-02 [37], PAMELA [38], and Fermi-LAT [39, 40], and cosmic ray anti-protons from PAMELA [41] These constraints will be supplemented by the LHC constraints such as monojet and diphoton signal strength measurement as well as constraint on the Higgs boson invisible decay width. These include: electroweak precision test constraints, W and Z width constraints, negative search for charginos and neutralinos from LEP-II that could restrict the inert Higgs bosons masses, diphoton signal strength measurement as well as monojet constraint from DM search at LHC. We briefly review the salient features of IHDM and discuss some existing theoretical constraints
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