Add to ORKGNonspherical perturbation theory has been necessary to understand the meaning of radiation in spacetimes generated through fully nonlinear numerical relativity. Recently, perturbation techniques have been found to be successful for the time evolution of initial data found by nonlinear methods. Anticipating that such an approach will prove useful in a variety of problems, we give here both the practical steps, and a discussion of the underlying theory, for taking numerically generated data on an initial hypersurface as initial value data and extracting data that can be considered to be nonspherical perturbations
We describe a numerical code that solves Einstein’s equations for a Schwarzschild black hole in sphe...
Einstein\u27s theory of general relativity has radically altered the way in which we perceive the un...
We consider the numerical evolution of dynamic black hole initial data sets with a full 3D, nonlinea...
Many simulations of gravitational collapse to black holes become inaccurate before the total emitted...
Black hole perturbation theory is typically studied on time surfaces that extend between the bifurca...
The perturbation theory of black holes has been useful recently for providing estimates of gravitati...
We study fully nonlinear and perturbative evolutions of nonrotating black holes with odd-parity dist...
The computation of gravitational radiation generated by the coalescence of inspiralling binary black...
The study of black holes and their interactions and the extraction of gravitational waves become of ...
We study fully nonlinear and perturbative evolutions of nonrotating black holes with odd-parity dist...
We present a new method for the calculation of black hole perturbations induced by extended sources ...
Numerical simulations of Kerr black holes are presented and the excitation of quasinormal modes is s...
We study gravitational perturbations of Schwarzschild spacetime by solving a hyperboloidal initial v...
The Bowen-York initial value data typically used in numerical relativity to represent spinning black...
We describe early success in the evolution of binary black-hole spacetimes with a numerical code bas...
We describe a numerical code that solves Einstein’s equations for a Schwarzschild black hole in sphe...
Einstein\u27s theory of general relativity has radically altered the way in which we perceive the un...
We consider the numerical evolution of dynamic black hole initial data sets with a full 3D, nonlinea...
Many simulations of gravitational collapse to black holes become inaccurate before the total emitted...
Black hole perturbation theory is typically studied on time surfaces that extend between the bifurca...
The perturbation theory of black holes has been useful recently for providing estimates of gravitati...
We study fully nonlinear and perturbative evolutions of nonrotating black holes with odd-parity dist...
The computation of gravitational radiation generated by the coalescence of inspiralling binary black...
The study of black holes and their interactions and the extraction of gravitational waves become of ...
We study fully nonlinear and perturbative evolutions of nonrotating black holes with odd-parity dist...
We present a new method for the calculation of black hole perturbations induced by extended sources ...
Numerical simulations of Kerr black holes are presented and the excitation of quasinormal modes is s...
We study gravitational perturbations of Schwarzschild spacetime by solving a hyperboloidal initial v...
The Bowen-York initial value data typically used in numerical relativity to represent spinning black...
We describe early success in the evolution of binary black-hole spacetimes with a numerical code bas...
We describe a numerical code that solves Einstein’s equations for a Schwarzschild black hole in sphe...
Einstein\u27s theory of general relativity has radically altered the way in which we perceive the un...
We consider the numerical evolution of dynamic black hole initial data sets with a full 3D, nonlinea...