A Supernova Early Warning System (SNEWS) that detects ghostlike neutrino particles that are the earliest emanations from the immense, explosive death throes of large stars will alert astronomers of the blasts before they can see the flash. SNEWS ”could allow astronomers a chance to make unprecedented observations of the very early turn-on of the supernova,” wrote the authors of an article about the new system in the September issue of the ”New Journal of Physics.”From Duke University:
Supernova warning system will give astronomers earlier notice
A Supernova Early Warning System (SNEWS) that detects ghostlike neutrino particles that are the earliest emanations from the immense, explosive death throes of large stars will alert astronomers of the blasts before they can see the flash.
SNEWS ”could allow astronomers a chance to make unprecedented observations of the very early turn-on of the supernova,” wrote the authors of an article about the new system in the September issue of the ”New Journal of Physics” http://www.iop.org/EJ/article/1367-2630/6/1/114/njp4_1_114.html.
They also noted that ”no supernova has ever been observed soon after its birth.”
Big stars end their lives in explosive gravitational collapses so complete that even the brilliant flashes of light usually announcing these extremely rare ”supernova” events stay trapped inside, unseen by astronomers, for the first hours or days.
Fortunately gravitational collapse supernovas also release large numbers of subatomic neutrinos that can immediately escape this maelstrom to zip into space at the same speed as light, according to Duke University assistant physics professor Kate Scholberg, one of the paper’s authors.
Neutrino bursts could thus afford the astronomical community its earliest possible alert of such supernovas, Scholberg and 20 authors wrote.
Their paper described SNEWS as an international collaboration of experimenters working at facilities that detect neutrinos, such as hers at Super-Kamiokande in Japan. ”The primary goal of SNEWS is to provide the astronomical community with a prompt alert for a galactic supernova,” the paper said.
SNEWS works by linking a central computer workstation at Brookhaven National Laboratory in New York with the other neutrino observatories worldwide, said Scholberg.
A neutrino physicist who was corresponding author of the ”New Journal of Physics” paper, she helped write the software for that computerized interconnection. This network can electronically compare data to increase scientists’ confidence that that a neutrino signal is really from a supernova.
The idea is that neutrino detectors sensing a type II supernova will ”basically light up at the same time,” she said. ”We can’t use just one detector because they are cranky enough to sometimes send out a fake alarm.”
”Natural” neutrinos can also be detected in radiation from the sun and from cosmic rays that strike Earth’s atmosphere, she said. Neutrinos can be produced artificially too by nuclear power plants and research accelerators. Among those natural and artificial sources, only solar neutrinos and those emitted by one type of accelerator have energy levels that can overlap those from a supernova, she added. Besides Super-Kamiokande, other charter member neutrino detector facilities in the SNEWS network are Sudbury Neutrino Observatory in Canada and the Large Volume Detector in Italy. Also participating in the SNEWS Working Group are collaborations behind eight other existing or planned facilities.
The new SNEWS network has not yet detected such a supernova. ”We don’t know when it will have an opportunity to perform a real detection: tomorrow, next month, next year, or in several decades from now, said noted astrophysicist John Bahcall of the Institute of Advanced Studies in Princeton, N.J.
These events occur ”no more than a few times per century,” Scholberg said. ”What that means is that if one happens you have to be really sure to get every possible piece of information from it. And it could be hours, or maybe even days before you actually see light coming out.”
A gravitational collapse supernova erupts when a star at least eight times more massive than our sun runs out of fuel. With the energy of nuclear fusion no longer available to support its massive internal structure, the giant star begins imploding drastically into a city-sized superdense neutron star.
Shortly after the stellar material collapses, a light-producing shock wave begins to fan out from the region of collapse. But it is the nature of particles of light — called photons — to interact with material they are passing through, in this case matter that is being squeezed into the densities of atomic nuclei, Scholberg said. As a result, light announcing the advent of a supernova cannot exit the region until the shock wave does, which can take hours and possibly days, Scholberg said.
But almost all the energy emanating from the collapsing star is actually in the form of neutrinos. ”They come out of supernovas like crazy,” she said.
A minority of neutrinos are produced from evolving supernovas when protons and neutrons are squeezed together to form neutrons. Most are created because conditions are hot and dense enough to create ”every kind of possible particle interaction,” Scholberg said.
”There is a phase where everything is so dense that even neutrinos are trapped, but that lasts only about 10 seconds,” she added. After that neutrinos are free to leave because they interact only rarely with matter. They are so elusive, in fact, that most pass through the entire Earth without hitting anything.
”SNEWS will be invaluable for astronomy and physics,” said Bahcall, who has advised the network’s organizers. ”Astronomers will rush with their telescopes that use ordinary light to observe the explosion in its earliest stages. And physicists throughout the world will pour over their recent data to study the details of the neutrino events from the supernova.
”We should have a wealth of new and unique results about the physical properties of neutrinos from the first discovery by SNEWS. And we will learn a lot of things about the interior of a stellar explosion that we could otherwise not study.”
The last gravitational collapse supernova to be observed near our Milky Way galaxy occurred in 1987 when a brilliant flash erupted at the location of a blue supergiant giant star named Sanduleak-69 202 in the Large Magellanic Cloud.
Its early observation by four different neutrino detectors operating at the time also ”brought the field of supernova neutrino astrophysics to life,” the authors of the ”New Journal of Physics” paper wrote.
Besides outpacing light in announcing the explosion, the neutrinos carried information that helped scientists confirm theories about gravitational collapses in such supernovas, their paper added. In addition, the information helped scientists define the limits of neutrino properties, such as neutrino masses.
The first of three known types of neutrinos were first experimentally observed only in 1956 and until recently all neutrinos were thought to be completely massless. The discovery that neutrinos actually have mass resulted in part from studies of cosmic ray neutrinos at Super-Kamiokande, Scholberg said.
That detector facility, located in an underground zinc mine, compared neutrinos emanating from the atmosphere above with those that had to pass through the earth from the atmosphere on the other side of the globe. Researchers found that neutrinos traveling the extra 13,000 kilometers changed forms — or ”flavors” — over the longer distances. ”The only way for that to happen is if they have mass,” Scholberg said.
Other detectors observing neutrinos from the sun, nuclear power plants and accelerators have observed similar ”oscillations” of neutrino flavors, said Scholberg, who recently relocated to Duke from MIT.
She noted that the organizers of SNEWS have established a connection with the worldwide community of amateur astronomers, who can sign up to be alerted if a supernova neutrino signal is detected.
”Amateurs may be among the first to find a visible supernova,” she said.