Cosmological consequences of Yukawa-unified SUSY with mixed axion/axino cold and warm dark matter

Abstract

Supersymmetric models with t-b-τ Yukawa unification at MGUT qualitatively predict a sparticle mass spectrum including first and second generation scalars at the 3--15 TeV scale, third generation scalars at the (few) TeV scale and gluinos in the sub-TeV range. The neutralino relic density in these models typically turns out to lie far above the measured dark matter abundance, prompting the suggestion that instead dark matter is composed of an axion/axino mixture. We explore the axion and thermal and non-thermal axino dark matter abundance in Yukawa-unified SUSY models. We find in this scenario that i). rather large values of Peccei-Quinn symmetry breaking scale fa 1012 GeV are favored and ii). rather large values of GUT scale scalar masses 10-15 TeV allow for the re-heat temperature TR of the universe to be TR 106 GeV. This allows in turn a solution to the gravitino/Big Bang Nucleosynthesis problem while also allowing for baryogenesis via non-thermal leptogenesis. The large scalar masses for Yukawa-unified models are also favored by data on b sγ and Bs μ+μ- decay. Testable consequences from this scenario include a variety of robust LHC signatures, a possible axion detection at axion search experiments, but null results from direct and indirect WIMP search experiments.