An international team of astronomers have created the longest consistent 3D model of a neutrino-driven supernova explosion to date, helping scientists to better understand the violent deaths of massive stars. The research, conducted using supercomputers in Australia, Germany, and the DiRAC facility in the UK, is published in the journal Monthly Notices of the Royal Astronomical Society.
Snapshot of the expansion of the neutrino-heated matter and the supernova shock wave during the explosion of an 18 solar mass star [Credit: Bernhard Müller] |
In the process, the outer layers of the star are expelled in a gigantic supernova explosion, which ejects material at velocities of thousands of kilometres per second. Such supernovae are regularly observed in distant galaxies, and within the Milky Way we can still see the debris of many of them thousands of years later.
But a puzzle remains: how is the collapse of the star turned into an explosion? The team, from Monash University, Queen’s University Belfast, and the Max Planck Institute for Astrophysics, have worked on a solution to this problem, and the most promising theory suggests that extremely light and weakly interacting particles called neutrinos are the key to this process.
Vast numbers of neutrinos are emitted from the surface of the young neutron star, and if the heating caused by the initial collapse is sufficiently strong, the neutrino-heated matter drives an expanding shock wave through the star and the collapse is reversed. Scientists have long attempted to show that this idea works with the help of computer simulations, but the computer models often still fail to explode, and can’t be run long enough to reproduce observed supernovae.
“What is crucial for success in three dimensions is the violent churning of hot and cold material behind the shock wave, which develops naturally due to the neutrino heating,” explains Dr Tobias Melson, a co-author of the study at the Max Planck Institute for Astrophysics in Germany. “But it often seems we need to stir these churning motions a bit more to obtain an explosion.”
To explore this possibility, the team simulated the fusion of oxygen to silicon in a star 18 times the size of our Sun, for the last 6 minutes before the supernova. They found that they could obtain a successful explosion because the collapsing silicon-oxygen shell was strongly stirred already.
They then followed the explosion for more than 2 seconds. Although it still takes about a day for the shock to reach the surface, they could tell that the explosion and the left-over neutron star were starting to look like the ones that we observe in nature.
“It’s reassuring that we now get plausible explosion models without having to tweak them by hand,” comments Dr Bernhard Mueller of the Monash Centre for Astrophysics in Australia, the lead author of the study.
Source: Monash University [September 15, 2017]
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