533 research outputs found
Revisiting Rotational Perturbations and the Microwave Background
We consider general-relativistic rotational perturbations in homogeneous and
isotropic Friedman - Robertson - Walker (FRW) cosmologies. Taking linear
perturbations of FRW models, the general solution of the field equations
contains tensorial, vectorial and scalar functions. The vectorial terms are in
connection with rotations in the given model and due to the Sachs - Wolfe
effect they produce contributions to the temperature fluctuations of the cosmic
microwave background radiation (CMBR). In present paper we obtain the analytic
time dependence of these contributions in a spatially flat, FRW model with
pressureless ideal fluid, in the presence and the absence of a cosmological
constant. We find that the solution can be separated into an integrable and a
non-integrable part as is the situation in the case of scalar perturbations.
Analyzing the solutions and using the results of present observations we
estimate the order of magnitude of the angular velocity corresponding to the
rotation tensor at the time of decoupling and today.Comment: accepted for publication in Int. J. Mod. Phys.
Covariant Linear Perturbations in a Concordance Model
We present the complete solution of the first order metric and density
perturbation equations in a spatially flat (K=0), Friedmann-Robertson-Walker
(FRW) universe filled with pressureless ideal fluid, in the presence of
cosmological constant. We use covariant linear perturbation formalism and the
comoving gauge condition to obtain the field and conservation equations. The
solution contains all modes of the perturbations, i.e. scalar, vector and
tensor modes, and we show that our results are in agreement with the Sachs &
Wolfe metric perturbation formalism.Comment: 8 page
Gravitational waves from binaries on unbound orbits
A generalized true anomaly-type parametrization, convenient to describe both
bound and open orbits of a two-body system in general relativity is introduced.
A complete description of the time evolution of both the radial and of the
angular equations of a binary system taking into account the first order
post-newtonian (1PN) is given. The gravitational radiation field emitted by the
system is computed in the 1PN approximation including higher multipole moments
beyond the standard quadrupole term. The gravitational waveforms in the time
domain are explicitly given up to the 1PN order for unbound orbits, but the
results are also illustrated on binaries on elliptic orbits with special
attention given to the effects of eccentricity.Comment: 27 pages, 10 figures, to appear in Phys. Rev.
Secular momentum transport by gravitational waves from spinning compact binaries
We present a closed system of coupled first order differential
equations governing the secular linear momentum loss of a
compact binary due to emitted gravitational waves, with the
leading order relativistic and spin-orbit perturbations
included. In order to close the system, the secular evolution
equations of the linear momentum derived from the dissipative
dynamics are supplemented with the secular evolutions of the
coupled angular variables, as derived from the conservative
dynamics © 2010 IOP Publishing Ltd
Principal null directions of perturbed black holes
The properties of principal null directions of a perturbed black hole are
investigated. It shown that principal null directions are directly observable
quantities characterizing the space-time. A definition of a perturbed
space-time, generalizing that given by Stewart and Walker is proposed. This
more general framework allows one to include descriptions of a given space-time
other than by a pair where is a four-dimensional differential
manifold and a Lorentz metric. Examples of alternative characterizations
are the curvature representation of Karlhede and others, the Newman-Penrose
representation or observable quantities involving principal null directions.
The conditions are studied under which the various alternative choices of
observables provide equivalent descriptions of the space-time.Comment: To appear in Class. Quantum Gra
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