Observable Gravity Waves From U(1)B-L Higgs and Coleman-Weinberg Inflation

Abstract

We present a realistic non-supersymmetric inflation model based on a gauged U(1)B-L symmetry and a tree-level Higgs potential. The inflaton is identified with the scalar field which spontaneously breaks U(1)B-L, and we include radiative corrections \`a la Coleman-Weinberg in the inflaton potential. If the scalar spectral index ns lies close to 0.96, as indicated by the recent Planck and WMAP 9-yr measurements, the tensor-to-scalar ratio r, a canonical measure for gravity waves, exceeds 0.01. Thus, according to this model, gravity waves should be found in the near future. In this case, the quantity |dns/d k| lies in the range 0.004-0.005. Successful baryogenesis can be realized in this class of models either via thermal or non-thermal leptogenesis.