ΛXCDM: a cosmon model solution to the cosmological coincidence problem?

Abstract: We consider the possibility that the total dark energy (DE) of the Universe is made out of two dynamical components of different nature: a variable cosmological term, Λ, and a dynamical "cosmon", X, possibly interacting with Λ but not with matter -which remains conserved. We call this scenario the ΛXCDM model. One possibility for X would be a scalar field χ, but it is not the only one. The overall equation of state (EOS) of the ΛXCDM model can effectively appear as quintessence or phantom energy depending on t… Show more

“…This problem has been addressed from different perspectives within modified quintessence models [17]. Remarkably, RG models can also tackle efficiently the coincidence problem [18], a point that will be reexamined here too.…”

“…In a subsequent work a general algorithm was established to compute the effective EOS for general cosmological models with variable cosmological parameters [20]. A further generalization (the so-called ΛXCDM models [18]) is to admit the possibility that the DE is a composite medium made out of a running Λ and a dynamical component X that we called the "cosmon" in [18] 3 . In the present work we elaborate further along this line but we allow the gravitational coupling G being variable.…”

“…(2.1) generalizes into 2) where ρ D = ρ Λ + ρ X is the total DE density. Following [18] we call the resulting composite DE model the ΛXCDM model. There are, however, different possible implementations of the ΛXCDM model: if we assume that ρ D and ρ m are separately conserved, then G must be constant and we obtain precisely the sort of ΛXCDM framework studied in detail in Ref.…”

“…There are, however, different possible implementations of the ΛXCDM model: if we assume that ρ D and ρ m are separately conserved, then G must be constant and we obtain precisely the sort of ΛXCDM framework studied in detail in Ref. [18], which will be referred hereafter as type I cosmon models. Alternatively, if we take as conserved quantities ρ X and ρ m , then we must haveρ i + α i ρ i H = 0 for both ρ i = ρ m , ρ X , and in this case (2.2) implies that G must vary in time in combination with ρ Λ according to the equatioṅ…”

“…if ω X < −1 and ρ X < 0 we obtain a kind of unusual fluid which has been called "phantom matter" (see Fig. 1 of [18]). Phantom matter does preserve -in contrast to usual phantom energy -the strong energy condition, as ordinary matter does.…”

Composite dark energy: Cosmon models with running cosmological term and gravitational coupling

“…This problem has been addressed from different perspectives within modified quintessence models [17]. Remarkably, RG models can also tackle efficiently the coincidence problem [18], a point that will be reexamined here too.…”

“…In a subsequent work a general algorithm was established to compute the effective EOS for general cosmological models with variable cosmological parameters [20]. A further generalization (the so-called ΛXCDM models [18]) is to admit the possibility that the DE is a composite medium made out of a running Λ and a dynamical component X that we called the "cosmon" in [18] 3 . In the present work we elaborate further along this line but we allow the gravitational coupling G being variable.…”

“…(2.1) generalizes into 2) where ρ D = ρ Λ + ρ X is the total DE density. Following [18] we call the resulting composite DE model the ΛXCDM model. There are, however, different possible implementations of the ΛXCDM model: if we assume that ρ D and ρ m are separately conserved, then G must be constant and we obtain precisely the sort of ΛXCDM framework studied in detail in Ref.…”

“…There are, however, different possible implementations of the ΛXCDM model: if we assume that ρ D and ρ m are separately conserved, then G must be constant and we obtain precisely the sort of ΛXCDM framework studied in detail in Ref. [18], which will be referred hereafter as type I cosmon models. Alternatively, if we take as conserved quantities ρ X and ρ m , then we must haveρ i + α i ρ i H = 0 for both ρ i = ρ m , ρ X , and in this case (2.2) implies that G must vary in time in combination with ρ Λ according to the equatioṅ…”

“…if ω X < −1 and ρ X < 0 we obtain a kind of unusual fluid which has been called "phantom matter" (see Fig. 1 of [18]). Phantom matter does preserve -in contrast to usual phantom energy -the strong energy condition, as ordinary matter does.…”

Composite dark energy: Cosmon models with running cosmological term and gravitational coupling

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