Astronomers have captured the earliest minutes of two exploding stars and for the first time seen a shockwave generated by a star’s collapsing core.

The international team found a shockwave only in the smaller supernova, a finding that will help them understand these complex explosions that create many of the elements that make up humans, the Earth and the solar system.

“It’s like the shockwave from a nuclear bomb, only much bigger, and no one gets hurt,” said Dr. Brad Tucker, from The Australian National University (ANU).

Stars explode when their fuel runs down and the core collapses. The resulting supernova explosion is brighter than the rest of its galaxy and shines for some weeks.

Supernovae are so bright that they can be seen in distant galaxies, which has helped astronomers learn much about the large-scale structure of the universe. However, very little is known about the early stages of these explosions.

The research, published in the Astrophysical Journal, reports the explosions of two old-age stars, red supergiants.

As the core of a supernova collapses to form a neutron star, energy bounces back from the core in the form of a shockwave that travels at 30,000 to 40,000 kilometers per second, and causes the nuclear fusion that creates heavy elements such as gold, silver and uranium.

The team from ANU and US institutions the University of Notre Dame, the Space Telescope Science Institute, the University of California Berkeley, and University of Maryland, saw a shockwave only in the smaller star with a radius 270 times that of the Sun, shown as a peak in the light emitted from the explosion in the first few days.

In the second star, a large supergiant with radius 460 times that of the Sun, a shockwave could not be detected, although it must have existed, said Dr. Tucker.

“The star was so large that the shockwave did not travel all the way to the surface,” he said.

The observation will help astronomers fine-tune their understanding of how the size and composition of the star affects the early moments of their explosive death.

“We are really probing the process of blowing up,” Dr. Tucker said.

“Supernovae made the heavy elements we need to survive, such as iron, zinc and iodine, so we are really learning about how we are created.”

Reference:

“Shock Breakout and Early Light Curves of Type II-P Supernovae Observed with Kepler,” P. M. Garnavich, B. E. Tucker, et al., 2016 March 20, Astrophysical Journal [http://iopscience.iop.org/article/10.3847/0004-637X/820/1/23, preprint: http://arxiv.org/abs/1603.05657].

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