A model of electroweakly interacting non-abelian vector dark matter

Self Cite

We study gamma-ray line signatures from electroweakly interacting non-abelian spin-1 dark matter (DM). In this model, Z2-odd spin-1 particles including a DM candidate have the SU(2)L triplet-like features, and the Sommerfeld enhancement is relevant in the annihilation processes. We derive the annihilation cross sections contributing to the photon emission and compare with the SU(2)L triplet fermions, such as Wino DM in the supersymmetric Standard Model. The Sommerfeld enhancement factor is approximately the same in both systems, while our spin-1 DM predicts the larger annihilation cross sections into γγ/Zγ modes than those of the Wino by $$ \frac{38}{9} $$ 38 9 . This is because a spin-1 DM pair forms not only J = 0 but also J = 2 partial wave states where J denotes the total spin angular momentum. Our spin-1 DM also has a new annihilation mode into Z2-even extra heavy vector and photon, Z′γ. For this mode, the photon energy depends on the masses of DM and the heavy vector, and thus we have a chance to probe the mass spectrum. The latest gamma-ray line search in the Galactic Center region gives a strong constraint on our spin-1 DM. We can probe the DM mass for ≲ 25.3 TeV by the Cherenkov Telescope Array experiment even if we assume a conservative DM density profile.

Section: Jhep10(2021)163mentioning

confidence: 99%

“…We briefly introduce a model of electroweakly interacting non-abelian vector DM [15]. We extend the electroweak gauge symmetry in the SM into SU (2)…”

Section: Modelmentioning

confidence: 99%

See 1 more Smart Citation

Gamma-ray line from electroweakly interacting non-abelian spin-1 dark matter

Abe

Fujiwara

Hisano

et al. 2021

Self Cite

“…gauge groups, such as SU(2) [21,[30][31][32][33][34][35][36][37][38][39][40][41][42][43], SU(2)⊗U(1) [44][45][46][47], SU(2)⊗SU(2) [48], SU(3) [21,35,[49][50][51][52], and general SU(N ) [21,35]. Typically, some discrete or global continuous symmetries remain after gauge symmetry breaking, stabilizing the vector DM particle.…”

Section: Introductionmentioning

confidence: 99%

Vector dark matter from split SU(2) gauge bosons

Cai

Tang

et al. 2021

We propose a vector dark matter model with an exotic dark SU(2) gauge group. Two Higgs triplets are introduced to spontaneously break the symmetry. All of the dark gauge bosons become massive, and the lightest one is a viable vector DM candidate. Its stability is guaranteed by a remaining Z2 symmetry. We study the parameter space constrained by the Higgs measurement data, the dark matter relic density, and direct and indirect detection experiments. We find numerous parameter points satisfying all the constraints, and they could be further tested in future experiments. Similar methodology can be used to construct vector dark matter models from an arbitrary SO(N) gauge group.

“…Vector boson DM (VDM) candidate can only appear in models with extended gauge group, the simplest being an Abelian U(1). Many possibilities of an Abelian VDM have been studied [19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37], while non-Abelian extensions to adopt VDM are fewer [38][39][40][41][42][43][44][45][46]. The VDM can become massive after spontaneous symmetry breaking of the additional gauge group and often requires additional stabilizing symmetry G DM [20,38].…”

Section: Introductionmentioning

confidence: 99%

Feebly coupled vector boson dark matter in effective theory

Barman

Bhattacharya

Grza̧dkowski

2020

A model of dark matter (DM) that communicates with the Standard Model (SM) exclusively through suppressed dimension five operator is discussed. The SM is augmented with a symmetry U(1)X ⊗ Z2, where U(1)X is gauged and broken spontaneously by a very heavy decoupled scalar. The massive U(1)X vector boson (Xμ) is stabilized being odd under unbroken Z2 and therefore may contribute as the DM component of the universe. Dark sector field strength tensor Xμν couples to the SM hypercharge tensor Bμν via the presence of a heavier Z2 odd real scalar Φ, i.e. 1/Λ XμνBμνΦ, with Λ being a scale of new physics. The freeze-in production of the vector boson dark matter feebly coupled to the SM is advocated in this analysis. Limitations of the so-called UV freeze-in mechanism that emerge when the maximum reheat temperature TRH drops down close to the scale of DM mass are discussed. The parameter space of the model consistent with the observed DM abundance is determined. The model easily and naturally avoids both direct and indirect DM searches. Possibility for detection at the Large Hadron Collider (LHC) is also considered. A Stueckelberg formulation of the model is derived.