Testing the EoS of dark matter with cosmological observations

Abstract

We explore the cosmological constraints on the parameter wdm of the dark matter barotropic equation of state (EoS) to investigate the "warmness" of the dark matter fluid. The model is composed by the dark matter and dark energy fluids in addition to the radiation and baryon components. We constrain the values of wdm using the latest cosmological observations that measure the expansion history of the Universe. When wdm is estimated together with the parameter wde of the barotropic EoS of dark energy we found that the cosmological data favor a value of wdm = 0.006 +- 0.001, suggesting a -warm- dark matter, and wde= -1.11 +- 0.03$ that corresponds to a phantom dark energy, instead of favoring a cold dark matter and a cosmological constant (wdm = 0, wde = -1). When wdm is estimated alone but assuming wde = -1, -1.1, -0.9, we found wdm = 0.009 +- 0.002, 0.006 +- 0.002, 0.012 +- 0.002 respectively, where the errors are at 3 sigma (99.73%), i.e., wdm > 0 with at least 99.73% of confidence level. When (wdm, dm0) are constrained together, the best fit to data corresponds to (wdm=0.005 +- 0.001, dm0 = 0.223 +- 0.008) and with the assumption of wde = -1.1 instead of a cosmological constant (i.e., wde = -1). With these results we found evidence of wdm > 0 suggesting a -warm- dark matter, independent of the assumed value for w de, but where values wde < -1 are preferred by the observations instead of the cosmological constant. These constraints on wdm are consistent with perturbative analyses done in previous works.