Statistics – Computation
Scientific paper
Dec 2000
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2000phdt.........6g&link_type=abstract
Thesis (PhD). THE UNIVERSITY OF UTAH, Source DAI-B 61/06, p. 3092, Dec 2000, 51 pages.
Statistics
Computation
Scientific paper
This thesis discusses two distinct problems, but both are related to black hole collisions. The ``close limit,'' a method based on perturbations of Schwarzschild spacetime, has proved to be a very useful tool for finding approximate solutions to models of black hole collisions. Calculations carried out with second order perturbation theory have been shown to give the limits of applicability of the method without the need for comparison with numerical relativity results. Those second order calculations have been carried out in a fixed coordinate gauge, a method that entails conceptual and computational difficulties. Here we demonstrate a gauge invariant approach to such calculations. For a specific set of models (requiring head on collisions and quadrupole dominance of both the first and second order perturbations), we give a self- contained gauge invariant formalism. Specifically, we give (i)wave equations and sources for first and second order gauge invariant wave functions; (ii)the prescription for finding Cauchy data for those equations from initial values of the first and second fundamental forms on an initial hypersurface; (iii)the formula for computing the gravitational wave power from the evolved first and second order wave functions. This first problem is discussed in Chapter 2. Initial data for black hole collisions are commonly generated using the Bowen-York approach based on conformally flat three geometries. The standard (constant Boyer-Lindquist time) spatial slices of the Kerr spacetime are not conformally flat, so that use of the Bowen-York approach is limited in dealing with rotating holes. We investigate here whether there exist foliations of the Kerr spacetime that are conformally flat. We limit our considerations to foliations that are axisymmetric and that smoothly reduce in the Schwarzschild limit to slices of constant Schwarzschild time. With these restrictions, we show that no conformally flat slices can exist. This second problem is discussed in Chapter 3.
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