Dark Matter Production in Weyl R2 Inflation

Abstract

Dark matter and inflation are two key elements to understand the origin of cosmic structures in modern cosmology, and yet their exact physical models remain largely uncertain. The Weyl scaling invariant theory of gravity may provide a feasible scheme to solve these two puzzles jointly, which contains a massive gauge boson playing the role of dark matter candidate, and allows the quadratic scalar curvature term, namely R2, to realize a viable inflationary mechanism in agreement with current observations. We ponder on the production of dark matters in the Weyl R2 model, including the contribution from the non-perturbative production due to the quantum fluctuations from inflationary vacuum and perturbative ones from scattering. We demonstrate that there are generally three parameter ranges for viable dark matter production: (1) If the reheating temperature is larger than 103~GeV, the Weyl gauge boson as dark matter can be produced abundantly with mass larger than the inflation scale 1013~GeV. (2) Small mass region with 3×10-13~GeV for a higher reheating temperature. (3) Annihilation channel becomes important in the case of higher reheating temperature, which enables the Weyl gauge boson with mass up to 4×1016~GeV to be produced through freeze-in.