A two-component dark matter model and its associated gravitational waves

A two-component dark matter model and its associated gravitational waves

A bstract We consider an extension of the Standard Model that accounts for the muon g − 2 tension and neutrino masses and study in detail dark matter phenomenology. The model under consideration includes a WIMP and a FIMP scalar dark matter candidates and thus gives rise to two-component dark matter...

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Veröffentlicht in:The journal of high energy physics 2022-06, Vol.2022 (6), p.26-39, Article 26
Hauptverfasser: Costa, Francesco, Khan, Sarif, Kim, Jinsu
Format: Artikel
Sprache:eng
Schlagworte:
Classical and Quantum Gravitation
Cosmology of Theories BSM
Dark matter
Elementary Particles
Experiments
Gravitational waves
High energy physics
Models for Dark Matter
Neutrinos
Particle Nature of Dark Matter
Phase transitions
Phase Transitions in the Early Universe
Phenomenology
Physics
Physics and Astronomy
Quantum Field Theories
Quantum Field Theory
Quantum Physics
Regular Article - Theoretical Physics
Relativity Theory
Scalars
Standard model (particle physics)
String Theory
Weakly interacting massive particles
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Zusammenfassung:A bstract We consider an extension of the Standard Model that accounts for the muon g − 2 tension and neutrino masses and study in detail dark matter phenomenology. The model under consideration includes a WIMP and a FIMP scalar dark matter candidates and thus gives rise to two-component dark matter scenarios. We discuss different regimes and mechanisms of production, including the novel freeze-in semi-production, and show that the WIMP and FIMP together compose the observed relic density today. The presence of the extra scalar fields allows phase transitions of the first order. We examine the evolution of the vacuum state and discuss stochastic gravitational wave signals associated with the first-order phase transition. We show that the gravitational wave signals may be probed by future gravitational wave experiments which may serve as a complementary detection signal.
ISSN:1029-8479
1029-8479
DOI:10.1007/JHEP06(2022)026