C. D. Ott, H. Dimmelmeier, A. Marek, H. -T. Janka, I. Hawke, B. Zink, E. Schnetter
Published 2006-09-29, updated 2007-05-01Version 2
We present results from the first 2D and 3D simulations of the collapse of rotating stellar iron cores in general relativity employing a finite-temperature equation of state and an approximate treatment of deleptonization during collapse. We compare fully nonlinear and conformally flat spacetime evolution methods and find that the conformally flat treatment is sufficiently accurate for the core-collapse supernova problem. We focus on the gravitational wave (GW) emission from rotating collapse, core bounce, and early postbounce phases. Our results indicate that the GW signature of these phases is much more generic than previously estimated. In addition, we track the growth of a nonaxisymmetric instability of dominant m = 1 character in one of our models that leads to prolonged narrow-band GW emission at ~930 Hz over several tens of milliseconds.
Comments: 4 pages, 4 figures, accepted for publication in Phys. Rev. Lett
Journal: Phys.Rev.Lett.98:261101,2007
Rotating Collapse of Stellar Iron Cores in General Relativity
Modeling Collisionless Matter in General Relativity: A New Numerical Technique
Black hole-neutron star binaries in general relativity: effects of neutron star spin
