Abstract
We propose a new paradigm for the thermal production of dark matter in the early universe, in which dark-matter particles acquire their mass and freeze out spontaneously from the thermal bath after a dark phase transition takes place. The decoupling arises because the dark-matter particles become suddenly non-relativistic and not because of any decay channel becoming kinematically close. We propose a minimal scenario in which a scalar and a fermionic dark-matter are in thermal equilibrium with the Standard-Model bath. We compute the finite temperature corrections to the scalar potential and identify a region of the parameter space where the fermionic dark-matter mass spontaneously jumps over the temperature when the dark phase transition happens. We explore the phenomenological implications of such a model in simple cases and show that the annihilation cross section of dark-matter particles has to be larger by more than one order of magnitude as compared to the usual constant-mass WIMP scenario in order to accomodate the correct relic abundance. We show that in the spontaneous freeze out regime a TeV-scale fermionic dark-matter that annihilates into leptons through s-wave processes can be accessible to detection in the near future.
Highlights
The nature of dark matter (DM) and the way it is produced in the early Universe stand among the biggest puzzles of modern cosmology
weakly interacting massive particle (WIMP) scenarios rely on two major ingredients, which are that (i) the dark-matter particles thermalize with the standard-model (SM) bath at high temperature, and that (ii) the cross section of annihilation of dark-matter particles into visible states is small enough in order to guarantee that the freeze out (FO) mechanism generates a sufficient DM relic abundance in the present Universe
We have focused on the simple case in which a dark-matter fermionic particle acquires its mass from the spontaneous breaking of a global Z2 symmetry, and is in thermal equilibrium with the standard-model bath
Summary
The nature of dark matter (DM) and the way it is produced in the early Universe stand among the biggest puzzles of modern cosmology. WIMP scenarios rely on two major ingredients, which are that (i) the dark-matter particles thermalize with the standard-model (SM) bath at high temperature, and that (ii) the cross section of annihilation of dark-matter particles into visible states is small enough in order to guarantee that the freeze out (FO) mechanism generates a sufficient DM relic abundance in the present Universe. Alternatives to the WIMP paradigm usually assume that dark-matter particles are produced out of equilibrium, either from the decay of a heavy particle (moduli and inflaton) [65,66] or from the feeble annihilation of particles that are thermalized with the standard-model bath [67,68,69,70,71,72] In all these different scenarios, the dark-matter mass and the.
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