Gravitational wave recoils in non-axisymmetric Robinson-Trautman spacetimes

Abstract

We examine the gravitational wave recoil waves and the associated net kick velocities in non-axisymmetric Robinson-Trautman spacetimes. We use characteristic initial data for the dynamics corresponding to non-head-on collisions of black holes. We make a parameter study of the kick distributions, corresponding to an extended range of the incidence angle 0 in the initial data. For the range of 0 examined (3 ≤ 0 ≤ 110) the kick distributions as a function of the symmetric mass parameter η satisfy a law obtained from an empirical modification of the Fitchett law, with a parameter C that accounts for the non-zero net gravitational momentum wave fluxes for the equal mass case. The law fits accurately the kick distributions for the range of 0 examined, with a rms normalized error of the order of 5 \%. For the equal mass case the nonzero net gravitational wave momentum flux increases as 0 increases, up to 0 55 beyond which it decreases. The maximum net kick velocity is about 190 km/s for for the boost parameter considered. For 0 ≥ 50 the distribution is a monotonous function of η. The angular patterns of the gravitational waves emitted are examined. Our analysis includes the two polarization modes present in wave zone curvature.