6533b833fe1ef96bd129c2d6
RESEARCH PRODUCT
Relativistic simulations of rotational core collapse : II. Collapse dynamics and gravitational radiation
Ewald MuellerHarald DimmelmeierJosé A. Fontsubject
Gravity (chemistry)FOS: Physical sciencesCollapse (topology)General Relativity and Quantum Cosmology (gr-qc)AstrophysicsAstrophysicsUNESCO::ASTRONOMÍA Y ASTROFÍSICAGeneral Relativity and Quantum CosmologyGravitational wavesGravitationGeneral Relativity and Quantum CosmologyNewtonian fluidGravitational waves ; Hydrodynamics ; Neutron Rotation ; SupernovaePhysicsGravitational waveNeutron RotationAstrophysics (astro-ph)Astronomy and AstrophysicsMechanics:ASTRONOMÍA Y ASTROFÍSICA::Cosmología y cosmogonia [UNESCO]SupernovaAmplitudeSupernovaeSpace and Planetary ScienceHydrodynamicsUNESCO::ASTRONOMÍA Y ASTROFÍSICA::Cosmología y cosmogoniaEvent (particle physics):ASTRONOMÍA Y ASTROFÍSICA [UNESCO]description
We have performed hydrodynamic simulations of relativistic rotational supernova core collapse in axisymmetry and have computed the gravitational radiation emitted by such an event. Details of the methodology and of the numerical code have been given in an accompanying paper. We have simulated the evolution of 26 models in both Newtonian and relativistic gravity. Our simulations show that the three different types of rotational supernova core collapse and gravitational waveforms identified in previous Newtonian simulations (regular collapse, multiple bounce collapse, and rapid collapse) are also present in relativistic gravity. However, rotational core collapse with multiple bounces is only possible in a much narrower parameter range in relativistic gravity. The relativistic models cover almost the same range of gravitational wave amplitudes and frequencies as the corresponding Newtonian ones. For a given model, relativistic gravity can cause a large increase of the characteristic signal frequency of up to a factor of five, which may have important consequences for the signal detection. The gravitational wave signals obtained in our study are within the sensitivity range of the first generation laser interferometer detectors if the source is located within the Local Group.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2002-04-17 |