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Astronomie - ‘What the heck is going on?’ Extremely high-energy particle detected falling to Earth

25.11.2023

Amaterasu particle, one of highest-energy cosmic rays ever detected, is coming from an apparently empty region of space

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Artist’s impression of the Amataresu particle. When ultra-high-energy cosmic rays hit Earth’s atmosphere, they initiate a cascade of secondary particles and electromagnetic radiation.Photograph: Osaka Metropolitan University/Kyoto University/Ryuunosuke Takeshige/PA

Astronomers have detected a rare and extremely high-energy particle falling to Earth that is causing bafflement because it is coming from an apparently empty region of space.

The particle, named Amaterasu after the sun goddess in Japanese mythology, is one of the highest-energy cosmic rays ever detected.

Only the most powerful cosmic events, on scales far exceeding the explosion of a star, are thought to be capable of producing such energetic particles. But Amaterasu appears to have emerged from the Local Void, an empty area of space bordering the Milky Way galaxy.

“You trace its trajectory to its source and there’s nothing high energy enough to have produced it,” said Prof John Matthews, of the University of Utah and a co-author of the paper in the journal Science that describes the discovery. “That’s the mystery of this – what the heck is going on?”

The Amaterasu particle has an energy exceeding 240 exa-electron volts (EeV), millions of times more than particles produced in the Large Hadron Collider, the most powerful accelerator ever built, and equivalent to the energy of a golf ball travelling at 95mph. It comes only second to the Oh-My-God particle, another ultra-high-energy cosmic ray that came in at 320 EeV, detected in 1991.

“Things that people think of as energetic, like supernova, are nowhere near energetic enough for this,” said Matthews. “You need huge amounts of energy, really high magnetic fields, to confine the particle while it gets accelerated.”

Toshihiro Fujii, an associate professor at Osaka Metropolitan University in Japan, said: “When I first discovered this ultra-high-energy cosmic ray, I thought there must have been a mistake, as it showed an energy level unprecedented in the last three decades.”

A potential candidate for this level of energy would be a super-massive black hole at the heart of another galaxy. In the vicinity of these vast entities, matter is stripped back to its subatomic structures and protons, electrons and nuclei are hurled out across the universe at nearly the speed of light.

Cosmic rays, echoes of such violent celestial events, rain down on to Earth nearly constantly and can be detected by instruments, such as the Telescope Array observatory in Utah, which found the Amaterasu particle.

Below a certain energy threshold, the flight path of these particles resembles a ball in a pinball machine as they zigzag against the electromagnetic fields through the cosmic microwave background. But particles with Oh-My-God or Amaterasu-level energy would be expected to blast through intergalactic space relatively unbent by galactic and extra-galactic magnetic fields, meaning it should be possible to trace their origin.

Tracing its trajectory backwards points towards empty space. Similarly, the Oh-My-God particle had no discernible source. Scientists suggest this could indicate a much larger magnetic deflection than predicted, an unidentified source in the Local Void, or an incomplete understanding of high-energy particle physics.

“These events seem like they’re coming from completely different places in the sky. It’s not like there’s one mysterious source,” said Prof John Belz of the University of Utah and a co-author of the paper. “It could be defects in the structure of spacetime, colliding cosmic strings. I mean, I’m just spitballing crazy ideas that people are coming up with because there’s not a conventional explanation.”

The Telescope Array is uniquely positioned to detect ultra-high-energy cosmic rays. It sits at about 1,200m (4,000ft), the elevation sweet spot that allows secondary particles maximum development, but before they start to decay. Its location in Utah’s West Desert provides ideal atmospheric conditions in two ways: the dry air is crucial because humidity will absorb the ultraviolet light necessary for detection; and the region’s dark skies are essential, as light pollution will create too much noise and obscure the cosmic rays.

The Telescope Array is in the middle of an expansion that that astronomers hope will help crack the case. Once completed, 500 new scintillator detectors will expand the Telescope Array across 2,900 km2 (1,100 mi2 ), an area nearly the size of Rhode Island and this larger footprint is expected to capture more of these extreme events.

This article was amended on 24 November 2023 to clarify some of the wording, based on agency copy, that was used in an earlier version regarding the speed of particles.

Quelle: The Guardian

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“Amaterasu” particle: a new cosmic mystery

Unknown extremely energetic particle from space detected and named after Japanese myth

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Ultra-high-energy cosmic ray captured by the Telescope Array experiment on May 27, 2021, dubbed “Amaterasu”
The detected cosmic ray had an estimated energy of 244 EeV, comparable to the most energetic cosmic ray ever observed 

Credit: Osaka Metropolitan University/L-INSIGHT, Kyoto University/Ryuunosuke Takeshige

Osaka, Japan – A high-energy particle falls from space to the Earth’s surface—it is not clear where it came from or even what it is, exactly. This may sound like something out of science fiction, but it is in fact a scientific reality, as evidenced by the research led by Associate Professor Toshihiro Fujii from the Graduate School of Science and Nambu Yoichiro Institute of Theoretical and Experimental Physics at Osaka Metropolitan University.
Cosmic rays are energetic charged particles originating from galactic and extragalactic sources. Cosmic rays with extremely high energy are exceptionally rare; they can reach greater than 1018 electron volts or one exa-electron volt (EeV), which is roughly a million times higher than achieved by the most powerful accelerators ever made by humans.
Chasing after such rays from space, Professor Fujii and an international team of scientists have been conducting the Telescope Array experiment since 2008. This specialized cosmic ray detector consists of 507 scintillator surface stations, covering an expansive detection area of 700 square kilometers in Utah, United States. On May 27, 2021, the researchers detected a particle with a whopping energy level of 244 EeV.
“When I first discovered this ultra-high-energy cosmic ray, I thought there must have been a mistake, as it showed an energy level unprecedented in the last 3 decades,” shared Professor Fujii.
Such an energy level is comparable to that of the most energetic cosmic ray ever observed, dubbed the “Oh-My-God” particle, which had an estimated energy of 320 EeV when detected in 1991.

Of the many candidates for the particle’s name, Professor Fujii and colleagues settled on “Amaterasu,” after the sun goddess that, according to Shinto beliefs, was instrumental in the creation of Japan.
The Amaterasu particle is perhaps as mysterious as the Japanese goddess herself. Where did it come from? What exactly was it? These questions remain. There is hope that the Amaterasu particle will pave the way for illuminating the origins of cosmic rays.
“No promising astronomical object matching the direction from which the cosmic ray arrived has been identified, suggesting possibilities of unknown astronomical phenomena and novel physical origins beyond the Standard Model,” Professor Fujii mused. “In the future, we commit to continue operating the Telescope Array experiment, as we embark, through our ongoing upgraded experiment with fourfold sensitivities, dubbed TAx4, and next-generation observatories, on a more detailed investigation into the source of this extremely energetic particle.”

Quelle: Osaka Metropolitan University

 

 

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