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A 4 Billion Light-Year Journey Ends At The South Pole

This artist's impression shows the dust torus around a super-massive black hole. Black holes lurk at the centers of active galaxies. The jets emanating from the black hole send neutrinos hurtling into space.
ESA/NASA/the AVO project/Paolo Padovani
This artist's impression shows the dust torus around a super-massive black hole. Black holes lurk at the centers of active galaxies. The jets emanating from the black hole send neutrinos hurtling into space.

Scientists for the first time have been able to pinpoint the source of an extremely powerful version of a neutrino, a ghostly particle that can travel virtually unimpeded through space.

It's an achievement that opens a whole new way of looking at the universe.

The neutrino was detected by a South Pole observatory called IceCube that was specifically designed to catch the particles. It consists of a cubic kilometer of ice festooned with more than 5,000 detectors.

Neutrinos don't interact with much, but occasionally one will strike another particle, giving off a kind of light known as Cherenkov radiation that IceCube's detectors can pick up.

When a particularly high-energy neutrino is captured, IceCube sends out an alert.

"We had this neutrino alert in September 2017," says Olga Botner, a particle physicist at Uppsala University in Sweden and a member of the National Science Foundation-funded IceCube scientific team. On Sept. 22, to be precise.

When the alert went out, a bevy of observatories on Earth and in space started searching the portion of the sky where the neutrino appeared to be coming from, looking for something that might have generated it.

There had been other alerts prior to last September, but past searches failed to turn up a viable candidate.

This time, as Botner and her colleagues report in the journal Science, two observatories, NASA's Fermi Gamma-ray Space Telescope and the Major Atmospheric Gamma Imaging Cherenkov telescope, saw a burst of gamma energy coming from the same location as the neutrino. Gamma rays are the kind of radiation one would expect to see from an object generating neutrinos. The object, known colloquially as TXS 0506+056, was something called a blazar approximately 4 billion light-years from Earth.

"Blazars are very special objects," Botner says. "They are intensely bright galaxies harboring a black hole at the center."

To confirm that TXS 0506+056 was indeed the source of the single energetic neutrino detected in September, Botner and her colleagues went back through nearly a decade of data IceCube had collected. They found that other energetic neutrinos had been detected from the same location but had not been previously associated with a celestial object. Those results appear in a second Science paper.

The neutrinos are expelled in jets that shoot out energetic particles from the black hole spinning inside the blazars.

"Those jets are a very interesting subject for astrophysicists," says astrophysicist Ke Fang, a JSI Prize postdoc fellow working at the University of Maryland and NASA Goddard Space Flight Center. "Because these are direct outputs from those black holes."

Fang says the hope is that more of these neutrinos will be detected, which should give physicists more information about the physics that govern black holes.

In fact, studying neutrinos given off by celestial objects will give scientists more information about cataclysmic events such as exploding stars and colliding neutron stars.

"Astronomy started when people looked at the night sky, and that's light hitting your eyes," says Naoko Kurahashi Neilson, an astrophysicist at Drexel University in Philadelphia and another member of the IceCube collaboration.

"It's expanded from just visible light to X-rays and gamma rays, and also to infrared and radio waves," she says.

But light waves and gamma rays and even radio waves are all what scientists call electromagnetic radiation. They differ in wave length, but they're all from the same family.

"And then here come neutrinos," Neilson says, "which is a completely different way to look at the universe. And gee, I wonder what we can see if we use this whole different way to look at the universe."

Of course, scientists don't know what they'll find, but then that's the whole point, isn't it?

Copyright 2021 NPR. To see more, visit https://www.npr.org.

Joe Palca is a science correspondent for NPR. Since joining NPR in 1992, Palca has covered a range of science topics — everything from biomedical research to astronomy. He is currently focused on the eponymous series, "Joe's Big Idea." Stories in the series explore the minds and motivations of scientists and inventors. Palca is also the founder of NPR Scicommers – A science communication collective.