Monster gamma ray burst in space sets record for death of star // Scientists predict new age of astronomy with discovery of the first sub-atomic neutrino particles from deep space
Astronomers call it the monster. It was the biggest and brightest cosmic explosion ever witnessed. Had it been closer, Earth would have been toast. Because the blast was 3.7bn light years away, mankind was spared. But orbiting telescopes got the fireworks show of a lifetime in April. The only bigger display astronomers know of was the big bang that created the universe, and no one was around to see that.
The blast was a gamma ray burst, an explosion that happens when a massive star dies, collapses into a brand-new black hole, creates a supernova and ejects energetic radiation that is as bright as can be as it travels across the universe at the speed of light. Nasa telescopes in orbit have been seeing these types of bursts for more than 20 years, spotting one every couple of days. But this one was special. It set records, according to four studies published on Thursday in the journal Science.
It flooded Nasa instruments with five times the energy of its nearest competitor, a blast in 1999, said University of Alabama at Huntsville astrophysicist Rob Preece, author of one of the studies. It started with a star that has 20 to 30 times the mass of our sun, but is only a couple of times bigger in width, so it is incredibly dense.
In general, gamma ray bursts are "the most titanic explosions in the universe" and this one was so big some of the telescope instruments hit their peak, Preece said. It was far stronger and lasted longer than previous ones. "I call it the monster," Preece said. And he wasn't alone. One of the other studies, not written by Preece, used the word "monster" in its title, unusual language for a scientific report.
One of the main reasons this was so bright was that relative to the thousands of other gamma ray bursts astronomers have seen, the monster was pretty close, even at 3.7bn light years. A light year is almost 6 trillion miles. Most of the bursts Nasa telescopes have seen have been twice as distant as this one. Other explosions could be this big, but are so much farther away they don't seem so bright when they get to Earth, the studies' authors say.
Astronomers say it is incredibly unlikely that a gamma ray burst – especially a big one like this – could go off in our galaxy, near us. Harvard's Avi Loeb, who wasn't part of the studies, put the odds at at least 1 in 10 million. Also, a burst has to be pointing at you to be seen and to be dangerous. It's concentrated like a focused searchlight or death beam. Planets caught in one would lose their atmospheres instantly and would be left a burnt cinder, astronomers say. "Either it's pointed at us or it's not," Preece said. "If it's not, yay! Civilisation survives and we see maybe a supernova. If it were pointed at us, then it matters very much how far away it is in our galaxy. If it's in our local arm, well, we had a good run."
We don't see gamma ray bursts on the surface of Earth because the atmosphere obscures them and because their light is the type we cannot see with our eyes, but Nasa has satellites that look for them. For scientists who look for gamma ray bursts, this was an extraordinary moment. "These are really neat explosions," said Peter Michelson, a Stanford physicist who is the chief scientist for one of the instruments on a Nasa gamma ray burst-spotting telescope. "If you like fireworks, you can't beat these. Other than the big bang itself, these are the biggest there are."
The burst "is part of the cycle of birth and life and death in the universe", Michelson said. "You and I are made of the stuff that came from a supernova."
An international team of researchers has confirmed the first detection of high-energy neutrinos - sub-atomic particles from beyond the Solar System - by highly sensitive optical instruments buried a mile deep in the ice sheet of Antarctic. Neutrinos from deep space normally pass straight through objects such as the Earth without being detected but the IceCube laboratory in Antarctic has now confirmed the tell-tale flashes of light from 28 highly energetic neutrinos it has identified since it began operating in 2011, scientists said. The breakthrough means that it is now possible to envisage a new class of telescopes based on neutrino detection. These could observe and measure cosmic phenomena that are difficult to detect with conventional telescopes, the researchers said.
"The era of neutrino astronomy has begun. The sources of neutrinos, and the question of what could accelerate these particles, have been a mystery for more than 100 years," said Professor Gregory Sullivan of the University of Maryland. "Now we have an instrument that can detect astrophysical neutrinos. It's working beautifully, and we expect it to run for another 20 years," said Professor Sullivan, one of the 260 scientists from 11 countries who are participating in the IceCube project...
