Abstract
The Petrov classification of stress-energy tensors provides a model-independent definition of a vacuum by the algebraic structure of its stress-energy tensor and implies the existence of vacua whose symmetry is reduced as compared with the maximally symmetric de Sitter vacuum associated with the Einstein cosmological term. This allows to describe a vacuum in general setting by dynamical vacuum dark fluid, presented by a variable cosmological term with the reduced symmetry which makes vacuum fluid essentially anisotropic and allows it to be evolving and clustering. The relevant solutions to the Einstein equations describe regular cosmological models with time-evolving and spatially inhomogeneous vacuum dark energy, and compact vacuum objects generically related to a dark energy: regular black holes, their remnants and self-gravitating vacuum solitons with de Sitter vacuum interiors—which can be responsible for observational effects typically related to a dark matter. The mass of objects with de Sitter interior is generically related to vacuum dark energy and to breaking of space-time symmetry. In the cosmological context spacetime symmetry provides a mechanism for relaxing cosmological constant to a needed non-zero value.
Highlights
Dark Energy is described by the equation of state p = wρ with w < −1/3 responsible for accelerated expansion ä ∼ − a(ρ + 3p)
In the Einstein equations with the cosmological constant Gν + λδν = 0; Gν = −λδν = −8πGTν the cosmological term corresponds to the de Sitter vacuum
In this paper we present the time-dependent and spatially inhomogeneous vacuum dark energy which is intrinsically related to the spacetime symmetry and can be evolving and clustering
Summary
The best fit, w = −1.06 ± 0.06 at 68% CL [1], corresponds to the cosmological constant λ related to the vacuum density ρvac by λ = 8πGρvac. In the Einstein equations with the cosmological constant Gν + λδν = 0; Gν = −λδν = −8πGTν the cosmological term corresponds to the de Sitter vacuum (false vacuum in the Standard Model). Alternative models typically impose ρvac = 0 for some reason (still unknown) and introduce a dark energy of a non-vacuum origin which mimics λ when necessary (for a review [2,3,4]). In this paper we present the time-dependent and spatially inhomogeneous vacuum dark energy which is intrinsically related to the spacetime symmetry and can be evolving and clustering
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