Horizon problem in a closed universe dominated by fluid with negative pressure
Abstract
We discuss the horizon problem in a universe dominated by fluid with negative pressure. We show that for generally accepted value of nonrelativistic matter energy density parameter m0<1, the horizon problem can be solved only if the fluid influencing negative pressure (the so-called ``X'' component) violates the point-wise strong energy condition and if its energy density is sufficiently large (X 0>1). The calculated value of the X0 parameter allowing for the solution of the horizon problem is confronted with some recent observational data. Assuming that pX/X<-0.6 we find that the required amount of the ``X'' component is not ruled out by the supernova limits. Since the value of energy density parameter v0 for cosmological constant larger than 1 is excluded by gravitational lensing observations the value of the ratio pX/X should lie between the values -1 and -0.6 if the model has to be free of the horizon problem beeing at the same time consistent with observations. The value of X0+m0 in the model is consistent with the constraints 0.2<tot<1.5 following from cosmic microwave background observations provided that m0 is low (<0.2).
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