A new way to test the WIMP dark matter models

In this paper, we investigate the possibility of testing the weakly interacting massive particle (WIMP) dark matter (DM) models by applying the simplest phenomenological model which introduces an interaction term between dark energy (DE) and WIMP DM, i.e., Q = 3γ_DMHρ_DM. In general, the coupling strength γ_DE is close to 0 as the interaction between DE and WIMP DM is very weak, thus the effect of γ_DE on the evolution of Y associated with DM energy density can be safely neglected. Meanwhile, our numerical calculation also indicates that x_f ≈ 20 is associated with DM freeze-out temperature, which is the same as the vanishing interaction scenario. As for DM relic density, it will be magnified by 2/−3 γ_DM 2 [2^{π g_∗m_DM3/(45 s₀x_f3 ]) γ_DM} times, which provides a new way to test WIMP DM models. As an example, we analyze the case in which WIMP DM is a scalar DM. (SGL+SNe+Hz) and (CMB+BAO+SNe) cosmological observations will give γ_DM = 0.134_−0.069^+0.17 and γ_DM = −0.0008 ± 0.0016, respectively. After further considering the constraints from DM direct detection experiment, DM indirect detection experiment, and DM relic density, we find that the allowed parameter space of the scalar DM model will be completely excluded for the former cosmological observations, while it will increase for the latter ones. Those two cosmological observations lead to an almost paradoxical conclusion. Therefore, one could expect more stringent constraints on the WMIP DM models, with the accumulation of more accurate cosmological observations in the near future.