Radiative Poincare type eon and its follower
Abstract
We consider two consecutive eons M and M from Penrose's Conformal Cyclic Cosmology and study how the matter content of the past eon (M) determines the matter content of the present eon (M) by means of the reciprocity hypothesis. We assume that the only matter content in the final stages of the past eon is a spherical wave described by Einstein's equations with the pure radiation energy momentum tensor Tij = KiKj, gij KiKj = 0, and with cosmological constant . We solve these Einstein's equations associating to M the metric g=t-2(-d t2+ht), which is a Lorentzian analog of the Poincar\'e-Einstein metric known from the theory of conformal invariants. The solution is obtained under the assumption that the 3-dimensional conformal structure [h] on the I+ of M is flat, that the metric g admits a power series expansion in the time variable t, and that h0∈ [h]. Such solution depends on one real arbitrary function of the radial variable r. Applying the reciprocal hypothesis, g g=t4g, we show that the new eon (M,g) created from the one containing a single spherical wave, is filled at its initial state with three types of radiation: (i) the damped spherical wave which continues its life from the previous eon, (ii) the in-going spherical wave obtained as a result of a collision of the wave from the past eon with the Bang hypersurface and (3) randomly scattered waves that could be interpreted as perfect fluid with the energy density and the isotropic pressure p such that p=13.
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