Wilsonian Dark Matter in String Derived $Z^\prime$ Model
Phys. Rev. D 96, 055025 (2017) The dark matter issue is among the most perplexing in contemporary physics. The problem is more enigmatic due to the wide range of possible solutions, ranging from the ultra-light to the super-massive. String theory gives rise to plausible dark matter candidates due to...
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Zusammenfassung: | Phys. Rev. D 96, 055025 (2017) The dark matter issue is among the most perplexing in contemporary physics.
The problem is more enigmatic due to the wide range of possible solutions,
ranging from the ultra-light to the super-massive. String theory gives rise to
plausible dark matter candidates due to the breaking of the non--Abelian Grand
Unified Theory (GUT) symmetries by Wilson lines. The physical spectrum then
contains states that do not satisfy the quantisation conditions of the unbroken
GUT symmetry. Given that the Standard Model states are identified with broken
GUT representations, and provided that any ensuing symmetry breaking is induced
by components of GUT states, leaves a remnant discrete symmetry that forbid the
decay of the Wilsonian states. A class of such states are obtained in a
heterotic-string derived $Z^\prime$ model. The model exploits the spinor-vector
duality symmetry, observed in the fermionic $Z_2\times Z_2$ heterotic-string
orbifolds, to generate a $Z^\prime\in E_6$ symmetry that may remain unbroken
down to low energies. The $E_6$ symmetry is broken at the string level with
discrete Wilson lines. The Wilsonian dark matter candidates in the string
derived model are $SO(10)$, and hence Standard Model, singlets and possess
non-$E_6$ $U(1)_{Z^\prime}$ charges. Depending on the $U(1)_{Z^\prime}$
breaking scale and the reheating temperature they give rise to different
scenarios for the relic abundance, and in accordance with the cosmological
constraints. |
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DOI: | 10.48550/arxiv.1704.02579 |