Causal propagation of geometrical fields in relativistic cosmology

Abstract

We employ the extended 1+3 orthonormal frame formalism for fluid spacetime geometries ( M, g, u), which contains the Bianchi field equations for the Weyl curvature, to derive a 44-D evolution system of first-order symmetric hyperbolic form for a set of geometrically defined dynamical field variables. Describing the matter source fields phenomenologically in terms of a barotropic perfect fluid, the propagation velocities v (with respect to matter-comoving observers that Fermi-propagate their spatial reference frames) of disturbances in the matter and the gravitational field, represented as wavefronts by the characteristic 3-surfaces of the system, are obtained. In particular, the Weyl curvature is found to account for two (non-Lorentz-invariant) Coulomb-like characteristic eigenfields propagating with v = 0 and four transverse characteristic eigenfields propagating with |v| = 1, which are well known, and four (non-Lorentz-invariant) longitudinal characteristic eigenfields propagating with |v| = 12. The implications of this result are discussed in some detail and a parallel is drawn to the propagation of irregularities in the matter distribution. In a worked example, we specialise the equations to cosmological models in locally rotationally symmetric class II and include the constraints into the set of causally propagating dynamical variables.

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