Thermal relics as hot, warm and cold dark matter in power-law f(R) gravity

Abstract

We investigate the thermal relics as hot, warm and cold dark matter in L=2-2βRβ+16πmPl-2Lm gravity, where is a constant balancing the dimension of the field equation, and 1<β<(4+6)/5 for the positivity of energy density and temperature. If light neutrinos serve as hot/warm relics, the entropic number of statistical degrees of freedom g*s at freeze-out and thus the predicted fractional energy density h2 are β-dependent, which relaxes the standard mass bound m. For cold relics, by exactly solve the simplified Boltzmann equation in both relativistic and nonrelativistic regimes, we show that the Lee-Weinberg bound for the mass of heavy neutrinos can be considerably relaxed, and the 'WIMP miracle" for weakly interacting massive particles (WIMPs) gradually invalidates as β deviates from β=1+. The whole framework reduces to become that of GR in the limit β 1+.