Journal
JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS
Volume -, Issue 8, Pages -Publisher
IOP PUBLISHING LTD
DOI: 10.1088/1475-7516/2016/08/035
Keywords
dark matter theory; physics of the early universe
Funding
- Science and Technology Facilities Council [ST/L000520/1, ST/J000418/1] Funding Source: researchfish
- STFC [ST/L000520/1, ST/J000418/1] Funding Source: UKRI
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Warm dark matter (WDM) of order keV mass may be able to resolve the disagreement between structure formation in cold dark matter simulations and observations. The detailed properties of WDM will depend upon its energy distribution, in particular how it deviates from the thermal distribution usually assumed in WDM simulations. Here we focus on WDM production via the Ultra Violet (UV) freeze-in mechanism, for the case of fermionic Higgs portal dark matter psi produced via the portal interaction (psi) over bar psi(HH)-H-dagger/Lambda. We introduce a new method to simplify the computation of the non-thermal energy distribution of (lark matter from freeze-in. We show that the non-thermal energy distribution from UV freeze-in is hotter than the corresponding thermal distribution and has the form of a Bose-Finstein distribution with a non-thermal normalization. The resulting range of dark matter fermion mass consistent with observations is 5-7 keV. The reheating temperature must satisfy T-R greater than or similar to 120 GeV in order to account for the observed dark matter density when in 5 keV, where the lower bound on T-R corresponds to the limit where the fermion mass is entirely due to electroweak symmetry breaking via, the portal interaction. The corresponding bound on the interaction scale is Lambda greater than or similar to 6.0 x 10(9) GeV.
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