Gravitational Wave Cosmology: High Frequency Approximation
Physical review D/Physical review D(2021)
Baylor Univ
Abstract
In this paper, we systematically study gravitational waves (GWs) first produced by remote compact astrophysical sources and then propagating in our inhomogeneous Universe through cosmic distances, before arriving at detectors. To describe such GWs properly, we introduce three scales, lambda, L-c, and L, denoting, respectively, the typical wavelength of GWs, the scale of the cosmological perturbations, and the size of the observable Universe. For GWs to be detected by the current and foreseeable detectors, the condition lambda << L-c << L holds. Then, such GWs can be approximated as high-frequency GWs and be well separated from the background gamma(mu nu) by averaging the spacetime curvatures over a scale l, where lambda << L << L-c , and g(mu nu) = gamma(mu nu) + epsilon h(mu nu) with h(mu nu) denoting the GWs. In order for the backreaction of the GWs to the background spacetimes to be negligible, we must assume that vertical bar h(mu nu)vertical bar << 1, in addition to the condition epsilon << 1, which are also the conditions for the linearized Einstein field equations for h(mu nu) to be valid. Such studies can be significantly simplified by properly choosing gauges, such as the spatial, traceless, and Lorenz gauges. We show that these three different gauge conditions can be imposed simultaneously, even when the background is not a vacuum, as long as the high-frequency GW approximation is valid. However, to develop the formulas that can be applicable to as many cases as possible, in this paper we first write down explicitly the linearized Einstein field equations by imposing only the spatial gauge. Then, applying these formulas together with the geometrical optics approximation to such GWs, we find that they still move along null geodesics and its polarization bivector is parallel transported, even when both the cosmological scalar and tensor perturbations are present. In addition, we also calculate the gravitational integrated Sachs-Wolfe effects due to these two kinds of perturbations, whereby the dependences of the amplitude, phase, and luminosity distance of the GWs on these perturbations are read out explicitly.
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