Showing papers by "John M. Blondin published in 2010"
TL;DR: In this paper, the gravitational wave signatures for a suite of axisymmetric core collapse supernova models with progenitor masses between 12 and 25 M have been presented, which are distinguished by the fact that they explode and contain essential physics (in particular, multi-frequency neutrino transport and general relativity).
Abstract: We present the gravitational wave signatures for a suite of axisymmetric core collapse supernova models with progenitor masses between 12 and 25 M⊙ These models are distinguished by the fact that they explode and contain essential physics (in particular, multi-frequency neutrino transport and general relativity) needed for a more realistic description Thus, we are able to compute complete waveforms (ie through explosion) based on non-parameterized, first-principles models This is essential if the waveform amplitudes and time scales are to be computed more precisely Fourier decomposition shows that the gravitational wave signals we predict should be observable by AdvLIGO across the range of progenitors considered here The fundamental limitation of these models is in their imposition of axisymmetry Further progress will require counterpart three-dimensional models
98 citations
TL;DR: The CHIMERA code as discussed by the authors is a supernova code developed to simulate core-collapse supernovae in 1, 2, and 3 spatial dimensions, and it has been used to simulate a variety of supernova types including 12, 15, 20, and 25.
Abstract: Much progress in realistic modeling of core-collapse supernovae has occurred recently through the availability of multi-teraflop machines and the increasing sophistication of supernova codes. These improvements are enabling simulations with enough realism that the explosion mechanism, long a mystery, may soon be delineated. We briefly describe the CHIMERA code, a supernova code we have developed to simulate core-collapse supernovae in 1, 2, and 3 spatial dimensions. We then describe the results of an ongoing suite of 2D simulations initiated from a 12, 15, 20, and 25 solar mass progenitor. These have all exhibited explosions and are currently in the expanding phase with the shock at between 5,000 and 20,000 km. We also briefly describe an ongoing simulation in 3 spatial dimensions initiated from the 15 solar mass progenitor.
63 citations
TL;DR: In this paper, a suite of axisymmetric core collapse supernova models with progenitors masses between 12 and 25 solar masses are distinguished by the fact they explode and contain essential physics (in particular, multifrequency neutrino transport and general relativity) needed for a more realistic description.
Abstract: We present the gravitational wave signatures for a suite of axisymmetric core collapse supernova models with progenitors masses between 12 and 25 solar masses. These models are distinguished by the fact they explode and contain essential physics (in particular, multi-frequency neutrino transport and general relativity) needed for a more realistic description. Thus, we are able to compute complete waveforms (i.e., through explosion) based on non-parameterized, first-principles models. This is essential if the waveform amplitudes and time scales are to be computed more precisely. Fourier decomposition shows that the gravitational wave signals we predict should be observable by AdvLIGO across the range of progenitors considered here. The fundamental limitation of these models is in their imposition of axisymmetry. Further progress will require counterpart three-dimensional models.
12 citations
TL;DR: In this article, both the macroscopic and microscopic effects that affect core-collapse supernovae are discussed, including neutrino-radiation-hydrodynamic simulations.
6 citations
TL;DR: The CHIMERA code as mentioned in this paper was developed to simulate core-collapse supernovae in 1, 2, and 3 spatial dimensions, and the results of an ongoing suite of 2D simulations initiated from a 12, 15, 20, and 25 solar mass progenitor.
Abstract: Unraveling the mechanism for core-collapse supernova explosions is an outstanding computational challenge and the problem remains essentially unsolved despite more than four decades of effort. However, much progress in realistic modeling has occurred recently through the availability of multi-teraflop machines and the increasing sophistication of supernova codes. These improvements have led to some key insights which may clarify the picture in the not too distant future. Here we briefly review the current status of the three explosion mechanisms (acoustic, MHD, and neutrino heating) that are currently under active investigation, concentrating on the neutrino heating mechanism as the one most likely responsible for producing explosions from progenitors in the mass range ~10 to ~25 solar masses. We then briefly describe the CHIMERA code, a supernova code we have developed to simulate core-collapse supernovae in 1, 2, and 3 spatial dimensions. We finally describe the results of an ongoing suite of 2D simulations initiated from a 12, 15, 20, and 25 solar mass progenitor. These have all exhibited explosions and are currently in the expanding phase with the shock at between 5,000 and 10,000 km. We finally very briefly describe an ongoing simulation in 3 spatial dimensions initiated from the 15 solar mass progenitor.
5 citations