Mystery Intergalactic Radio Bursts Detected
Astronomers were on a celestial fishing expedition for pulsing neutron stars and other radio bursts when they found something unexpected in archived sky sweeps conducted by the Parkes radio telescope in New South Wales, Australia.
Analysis later indicated that, unlike most cosmic radio signals that originate in the Milky Way or a nearby neighbor galaxy, these four seem to have come from beyond.
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Whatever triggered the bursts has come and gone. The signals, detected between February 2011 and January 2012, were one-time events so little follow-up work can be done.
What is known is that in just a few milliseconds, each of the signals released about as much energy as the sun emits in 300,000 years.
“They have come such a long way that by the time they reach the Earth, the Parkes telescope would have to operate for 1 million years to collect enough to have the equivalent energy of a flying mosquito,” astronomer Dan Thornton, with the University of Manchester in the United Kingdom, wrote in an email to Discovery News.
Scientists have all kinds of theories about what exotic phenomena may have triggered the bursts. The contenders include colliding magnetars, which are neutron stars with super-strong magnetic fields; evaporating black holes; and gamma ray bursts that involve a supernova.
Or, as Cornell University astronomer James Cordes points out, the bursts could be from an entirely new type of high-energy astrophysical event.
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“It is still early days for identifying the astrophysical origins of such common but (so far) rarely detected events,” Cordes wrote in an article published in this week’s Science.
Whatever is happening is probably a relatively common, though difficult to detect, phenomenon. Extrapolating from the research, astronomers estimate there are as many as about 10,000 similar high-energy millisecond radio bursts happening across the sky every day.
“This might seem common, and it is, but you need a big telescope to detect them,” Thornton said.
Typically, telescopes only look at a very small patch of the sky at any one time, he added, “so you have to look for a long time before seeing many. This is why we have only detected a handful so far.”
Similar radio signals have been found before, but astronomers could never nail down whether they came from inside or beyond the galaxy.
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Thornton and his team did so by characterizing the plasma the radio waves had to travel through before reaching the telescope. The shape of the wave is impacted by the amount of plasma along the signal’s path.