Abstract
Complete set of modes and the Hadamard function are constructed for a scalar field inside and outside a sphere in (D+1)-dimensional de Sitter spacetime foliated by negative constant curvature spaces. We assume that the field obeys Robin boundary condition on the sphere. The contributions in the Hadamard function induced by the sphere are explicitly separated and the vacuum expectation values (VEVs) of the field squared and energy-momentum tensor are investigated for the hyperbolic vacuum. In the flat spacetime limit the latter is reduced to the conformal vacuum in the Milne universe and is different from the maximally symmetric Bunch-Davies vacuum state. The vacuum energy-momentum tensor has a nonzero off-diagonal component that describes the energy flux in the radial direction. The latter is a purely sphere-induced effect and is absent in the boundary-free geometry. Depending on the constant in Robin boundary condition and also on the radial coordinate, the energy flux can be directed either from the sphere or towards the sphere. At early stages of the cosmological expansion the effects of the spacetime curvature on the sphere-induced VEVs are weak and the leading terms in the corresponding expansions coincide with those for a sphere in the Milne universe. The influence of the gravitational field is essential at late stages of the expansion. Depending on the field mass and the curvature coupling parameter, the decay of the sphere-induced VEVs, as functions of the time coordinate, is monotonic or damping oscillatory. At large distances from the sphere the fall-off of the sphere-induced VEVs, as functions of the geodesic distance, is exponential for both massless and massive fields.
Highlights
The quantum field-theoretical effects in background of de Sitter spacetime continue to be the subject of active research
On the basis of this, one can reveal the features of the influence of gravitational fields on quantum effects in more complicated geometries, including those describing a more general class of cosmological models and black hole physics
The most inflationary models for the expansion of the early Universe are based on an approximately de Sitter (dS) geometry sourced by slowly evolving scalar fields
Summary
The quantum field-theoretical effects in background of de Sitter (dS) spacetime (for geometrical properties and coordinate systems see, for instance, [1,2]) continue to be the subject of active research. Motivated by radion stabilization and generation of the cosmological constant on branes, the investigation of boundary-induced quantum effects in anti–de Sitter spacetime has attracted a great deal of attention (see references given in [13,14]). The VEVs of the field squared and energy-momentum tensor for scalar and electromagnetic fields induced by a cylindrical boundary in dS bulk have been investigated in [22,23] Another class of exactly solvable problems correspond to spherical boundaries. In the present paper we investigate the influence of a spherical boundary on the vacuum fluctuations of a massive scalar field in background of (D þ 1)-dimensional dS spacetime with negative curvature spatial foliation for the general curvature coupling. In Appendix B the expression for the Hadamard function in the boundary-free dS spacetime with negative curvature spatial foliation is presented without specifying the vacuum state
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