Two dark components of de Sitter Universe

The de Sitter vacuum serves as the thermal bath for matter with local temperature, which is twice the Gibbons-Hawking temperature related to the cosmological horizon. This local temperature leads to the heating of matter. Here do not consider the real matter, but only the component which is related to the gravitational degrees of freedom and participates the thermodynamics of the de Sitter state. This gravitational component behaves as Zel'dovich stiff matter. The vacuum energy and the analog of the Zel'dovich stiff matter represent correspondingly the dark energy and dark matter. In equilibrium the positive partial pressure of dark matter compensates the negative partial pressure of quantum vacuum. That is why in the full equilibrium the total pressure is zero. This is rather similar to the correspondingly superfluid and normal components of superfluid liquid, which together produce the zero pressure of the liquid in the absence of environment. We extend this two dark components approach and the suggest the phenomenological theory, which describes the dynamics of the dark energy and the dark matter. For that we assume that the in dynamics, the gravitational dark matter also behaves as the real Zel'dovich stiff matter. In this phenomenological model, both components experience the power law decay due to the energy exchange between these components. Then it follows that their values at present time have the correct order of magnitude. How this phenomenology is supported by the microscopic physics is an open question.