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Cosmic horizon in the de Sitter space is a sphere, centered at the observer with finite radius where the red shift due to cosmic expansion becomes infinite.

Given that no information can be transmitted from behind the cosmic horizon, I wonder whether any matter can ever pass behind the event horizon, because this will give rise to an information paradox, similar to the black hole information paradox.

The matter approaching the cosmic horizon seems to experience time dilation, so will that time dilation prevent it from crossing the horizon?

To work around the paradox, one have to postulate that the information about outgoing matter should be encoded in the de Sitter radiation.

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  • $\begingroup$ Are you asking about a de Sitter universe, our universe at the present time, or when (in theory) our universe becomes a de Sitter universe in the future? "None of the above" is fine, too, with some explanation. $\endgroup$ – HDE 226868 Oct 5 '14 at 20:30
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A little bit of caution is needed when approaching this subject as there are several surfaces in cosmological solutions that can be interpreted (or misinterpreted in some cases) as horizons. Not all of them appear in all comsological solutions and in some cosmological solutions some of these surfaces are only present for part of the evolution of the solution.

If you were to mean the particle horizon, which is the limit of the observable Universe. The cosmological red shift at the particle horizon is always infinite, when there is a particle horizon. No matter can ever leave the particle horizon (regardless of the cosmological model, as long as there is a particle horizon) as it expands radially outwards at a local speed of c relative to any matter on the horizon (of course to us it expands even faster than c as it is also receding due to expansion).

An ever-expanding Universe with a cosmological constant approaches a state similiar to de Sitter space in late times, however de Sitter space itself is not a realistic cosmological solution as it is devoid of matter. De Sitter space does not have a particle horizon and for that matter it doesn't have any singularities either.

In de Sitter space the cosmic event horizon, which is the surface beyond which events happening now cannot affect us in the future providing we stay at the same spot (this should not be confused with the particle horizon), sits at a constant distant to the observer that is inversely proportional to the square root of the cosmological constant.

In answer to your question then, de Sitter space is symmetric in time and space which actually gives rise to seemingly different physical interpretations of it. However the black hole information paradox is specifically the loss of unitariness in the time evolution of a black hole and you have not justified why you think an equivalent thing should happen in de Sitter space. The loss of unitariness in actually arises because the event horizon disappears, but (naively at least) the information behind it also disappears. In de Sitter space the event horizon remains and even if it were to disappear by the cosmological constant miraculously going to zero we would still find the information behind it, so there is no analog to the information paradox in de Sitter space.

To take another example, consider Rindler coordinates in Minkowski spacetime, there is a horizon (the Rindler horizon) and there is radiation (Unruh radiation), however there is no information paradox as we know that unitariness is preserved in Minkowski spacetime and when the Rindler horizon is made to disappear by selecting a different coordinate system, all the information that was behind the horizon is still there.

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  • $\begingroup$ "it expands radially outwards at a local speed of c relative to any matter on the horizon" - no regarding matter on the horizon it approaches the observer "of course to us it expands even faster than c as it is also receding due to expansion" - the greater the expansion, the closer the horizon to the observer. $\endgroup$ – Anixx Oct 5 '14 at 23:14
  • $\begingroup$ @Anixx, that is not true. The distance to the particle horizon depends on the amount of cosmological time that has passed since the big bang singularity and the history of the expansion from the big bang to the present. It is independent of the current rate of expansion. I think you are confused with the Hubble sphere in de Sitter space which depends on the value of the cosmological constant. In de Sitter space, the larger the cosmological constant, the nearer the Hubble sphere, but the Hubble sphere is not a horizon in itself. $\endgroup$ – John Davis Oct 5 '14 at 23:25
  • $\begingroup$ I am talking about de Sitter event horizon because the question is explicitely about de Sitter space (which does not have a particle horizon). $\endgroup$ – Anixx Oct 5 '14 at 23:28
  • $\begingroup$ I understand you now, in de Sitter space the Hubble sphere coincides with the event horizon. I will amend my answer. $\endgroup$ – John Davis Oct 5 '14 at 23:32

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