Inflation and dark matter after spontaneous Planck scale generation by hidden chiral symmetry breaking

Dynamical chiral symmetry breaking in a QCD-like hidden sector is used to generate the Planck mass and the electroweak scale including the heavy right-handed neutrino mass. A real scalar field transmits the energy scale of the hidden sector to the visible sectors, playing besides a role of inflaton in the early Universe while realizing a Higgs-inflation-like model. Our dark matter candidates are hidden pions that raise due to dynamical chiral symmetry breaking. They are produced from the decay of inflaton. Unfortunately, it will be impossible to directly detect them, because they are super heavy (10(9 similar to 12 )GeV), and moreover the interaction with the visible sector is extremely suppressed.

Automated summary

Utilizing dynamical chiral symmetry breaking in a QCD-like hidden sector to generate the Planck mass and the electroweak scale, the study proposes hidden pions as dark matter candidates. However, due to their super heavy mass (10^9 to 10^12 GeV) and extremely suppressed interaction with the visible sector, direct detection of these hidden pions is not feasible.