Dynamically Induced Topological Inflation

Abstract

We propose an inflation model in which the inflationary era is driven by the strong dynamics of Sp(2) gauge theory. The quark condensation in the confined phase of Sp(2) gauge theory generates the inflaton potential comparable to the energy of the thermal bath at the time of phase transition. Afterwards, with super-Planckian global minimum, the inflation commences at a false vacuum region lying between true vacuum regions and hence the name "topological inflation". Featured by the huge separation between the scale of the false vacuum (V(0)1/41015 GeV) and the global minimum (φ MP), the model can be consistent with CMB observables without suffering from the initial condition problem. Crucially, this is achieved without any fine-tuning of parameters in V(φ). In addition to Sp(2), this model is based on an anomaly free Z6R discrete R symmetry. Remarkably, while all parameters are fixed by CMB observations, the model predicts a hierarchy of energy scales including the inflation scale, SUSY-breaking scale, R-symmetry breaking scale, Higgsino mass and the right-handed neutrino mass given in terms of the dynamical scale of Sp(2).