Thermal misalignment of scalar dark matter
Brian Batell, Akshay Ghalsasi
Abstract
The conventional misalignment mechanism for scalar dark matter depends on the initial field value, which governs the oscillation amplitude and present-day abundance. We discuss a mechanism by which a feeble coupling of dark matter to a fermion in thermal equilibrium drives the scalar toward its high-temperature potential minimum at large field values, dynamically generating misalignment before oscillations begin. Unlike conventional misalignment production, the dark matter abundance is dictated by microphysics and not by initial conditions. As an application of the generic mechanism, we discuss a realistic scenario in which dark matter couples to the muon.
Topics & Concepts
PhysicsDark matterScalar field dark matterScalar fieldScalar (mathematics)ThermalDark fluidOscillation (cell signaling)FermionQuantum electrodynamicsParticle physicsDark energyAstrophysicsClassical mechanicsCosmologyThermodynamicsGeneticsBiologyMathematicsGeometryDark Matter and Cosmic PhenomenaCosmology and Gravitation TheoriesParticle physics theoretical and experimental studies