杏吧原创

Violent black holes spit neutrinos at Earth and we finally caught one

For the first time, we have traced a high-energy neutrino back to its origin - a black hole 4 billion light years away - and solved an old cosmic mystery
Tracking down elusive neutrinos
Tracking down elusive neutrinos
NASA/JPL-Caltech

Neutrinos are some of the weirdest and most mysterious particles in the universe, but we are starting to learn more about their origins. For the first time, a team of researchers has traced a single high-energy neutrino back to its birthplace, a supermassive black hole around 4 billion light years away.

On 22 September last year, a blue light pulsed through the ice deep under the South Pole. This light was generated by a high-energy neutrino passing through Earth and picked up by an experiment called the IceCube detector that traced the path of the light 聽back to the direction the neutrino came from.

Less than a minute later, IceCube sent an automated alert to astronomers around the world, telling them to turn their telescopes on a small area in the sky. They scrambled to look for anything bright that might be generating high-energy protons, which interact with other matter and light to create neutrinos.

A few days later, observers using NASA鈥檚 Fermi space telescope reported that the neutrino鈥檚 path pointed back in the direction of a blazar 鈥 a supermassive black hole blasting out a jet of particles 鈥 that was experiencing a huge flare, and likely producing neutrinos.

Spectacular first

鈥淭his is a pretty spectacular first,鈥 says IceCube spokesperson Darren Grant. 鈥淚t鈥檚 the first compelling evidence of a high-energy neutrino being measured from where it originated.鈥 And it鈥檚 only the third time we鈥檝e found a specific cosmic object creating neutrinos, the other two being the sun and a nearby supernova in 1987.

When IceCube researchers went back through almost a decade of data, they found 13 other neutrinos that seem to have come from the same direction in 2014 and 2015. They came in before the alert system was online, and wouldn鈥檛 have been quite high-energy enough to trigger an alert anyway.

Find out more at New 杏吧原创 Live:

鈥淚t doesn鈥檛 seem like much, but prior to this the best source that we鈥檝e ever looked at had three neutrinos coming from it,鈥 says IceCube team member Josh Woods.

With Fermi pin-pointing the source, other telescopes turned to look at the blazar, taking observations in wavelengths across the electromagnetic spectrum. It鈥檚 extremely bright in many wavelengths, making it able to accelerate protons to the extremely high energies required to create September鈥檚 neutrino. Researchers also measured its distance, which wasn鈥檛 precisely known before, at about 4 billion light years away.

Mystery solved

The find solves a long-lasting mystery, one that鈥檚 been around since 1912, when astronomers first spotted another kind of high-energy particle from space called cosmic rays. Unlike neutrinos, cosmic rays interact with magnetic fields as they travel, giving them twisting and turning paths. That means we鈥檝e never definitively pinpointed a source of cosmic rays.

But cosmic rays are mostly protons 鈥 the same protons that create high-energy neutrinos 鈥 so the blazar that produced the neutrinos must also be producing some high-energy cosmic rays.

Blazars can鈥檛 be responsible for producing all of the high-energy neutrinos and cosmic rays that we see, simply because there aren鈥檛 enough of them. Some must come from other violent environments and processes in the sky such as supernovae and gamma ray bursts, but having such detailed observations of one source may help us narrow down exactly how they鈥檙e produced.

Fitting everything into one coherent picture will be very challenging, says Brad Cenko at NASA鈥檚 Goddard Space Flight Center in Maryland. The processes that create both neutrinos and light across the electromagnetic spectrum seem more complicated than we predicted, and we are not even completely sure what they are yet, he says.

But as neutrino detectors continue to improve, we are likely to find many more sources with more high-energy neutrinos associated with them. Then, we鈥檒l be able to use neutrinos to probe how these cosmic particle accelerators work.

鈥淭he idea that neutrino astronomy works has really come to reality now,鈥 says Grant. 鈥淔or the longest time, people studied the cosmos through the electromagnetic spectrum, and recently we added gravitational waves which was just an incredible breakthrough, and now neutrinos join that party.鈥

Journal reference:听Science,听;听

Topics: Black holes / Cosmic rays / Neutrinos