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Canadian scientists are part of an international team that, for the first time, followed a tiny deformation of the material to its source in deep space.
David Sivakoff, astronomer of the University of Alberta, says: Black hole at four billion light-years away will give researchers a whole new way to probe the most exotic secrets from the universe
He says that it is the equivalent of developing a sixth sense
detected in IceCube, an Antarctic neutrino detector made from a cubic kilometer solid ice.
"This whole project is an interesting mix of scientists whose work began with IceCube Alerts and Astronomer's Telegrams." Sivakoff said:
This is a high neutrino energy detected by IceCube on September 22, 2017. With an estimated energy of 290 TeV, it was the tenth warning of this guy sent by IceCube to the international astronomical community and launched a series of multimessenger observations that helped identify the first source
Credit: IceCube Collaboration
To help From observations of astronomers from around the world, scientists spotted the particle in a black hole in the center of the blazar, a type of supermbadive galaxy. black hole in his heart.
This impression of the artist shows the torus around a super-mbadive black hole. Black holes are hidden at the centers of active galaxies in environments similar to those found in violent tornadoes on Earth. As in a tornado, where we often find debris that revolves around the vortex, a torus of dust surrounds its size in a black hole
Source: ESA / NASA, AVO Project and Paolo Padovani
" We "testify the benefits of combining the talents of astrophysicists and particle physicists, combining not only the detection of photons but also new messengers such as astrophysical neutrinos, like the one announced today. "
Sivakoff says that tying the particle to its source will allow astronomers to study the stars using a completely new type of energy.
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