Unification of Inflation with Dark Energy in f(R) Gravity and Axion Dark Matter

Abstract

In this work we introduce an effective model of f(R) gravity containing a non-minimal coupling to the axion scalar field. The axion field is described by the misalignment model, in which the primordial U(1) Peccei-Quinn symmetry is broken during inflation and the f(R) gravity is described by the R2 model, and in addition, the non-minimal coupling has the form h(φ)Rγ, with 0<γ<0.75. By appropriately constraining the non-minimal coupling at early times, the axion field remains frozen in its primordial vacuum expectation value, and the R2 gravity dominates the inflationary era. As the Universe expands, when H equals the axion mass ma and for cosmic times for which ma H, the axion field oscillates. By assuming a slowly varying evolution of the axion field, the axion energy density scales as a a-3, where a is the scale factor, regardless of the background Hubble rate, thus behaving as cold dark matter. At late times, the axion still evolves as a a-3, however the Hubble rate of the expansion and thus the dynamical evolution of the Universe is controlled by terms containing the higher derivatives of Rγ, which are related to the non-minimal coupling, and as we demonstrate, the resulting solution of the Friedman equation at late times is an approximate de Sitter evolution. The late-time de Sitter Hubble rate scales as H 1/2, where is an integration constant of the theory, which has its allowed values very close to the current value of the cosmological constant. Finally, the theory has a prediction for the existence of a pre-inflationary primordial stiff era, in which the energy density of the axion scales as a a-6.