Early dark energy from zero-point quantum fluctuations

We examine a cosmological model with a dark energy density of the form ρDE(t)=ρX(t)+ρZ(t), where ρX is the component that accelerates the Hubble expansion at late times and ρZ(t) is an extra contribution proportional to H2(t). This form of ρZ(t) follows from the recent proposal that the contribution...

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Bibliographic Details
Published in:Physics letters. B 2011-10, Vol.704 (3), p.102-107
Main Authors: Maggiore, Michele, Hollenstein, Lukas, Jaccard, Maud, Mitsou, Ermis
Format: Article
Language:English
Subjects:
Computation
Cosmological constant
Dark energy
Density
Divergence
Early dark energy
Elementary particles
Energy density
Exact sciences and technology
Fluctuation
Nuclear physics
Physics
The physics of elementary particles and fields
Vacuum fluctuations
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Summary:We examine a cosmological model with a dark energy density of the form ρDE(t)=ρX(t)+ρZ(t), where ρX is the component that accelerates the Hubble expansion at late times and ρZ(t) is an extra contribution proportional to H2(t). This form of ρZ(t) follows from the recent proposal that the contribution of zero-point fluctuations of quantum fields to the total energy density should be computed by subtracting the Minkowski-space result from that computed in the FRW space–time. We discuss theoretical arguments that support this subtraction. By definition, this eliminates the quartic divergence in the vacuum energy density responsible for the cosmological constant problem. We show that the remaining quadratic divergence can be reabsorbed into a redefinition of Newtonʼs constant only under the assumption that ∇μ〈0|Tμν|0〉=0, i.e. that the energy–momentum tensor of vacuum fluctuations is conserved in isolation. However in the presence of an ultra-light scalar field X with mX
ISSN:0370-2693
1873-2445
DOI:10.1016/j.physletb.2011.09.010