Thursday, November 23, 2023

Mysterious cosmic ray observed in Utah came from beyond our galaxy, scientists say

KATIE HUNT CNN

Few things in space are as bright as a supernova, but recently astronomer captured a flash out in the cosmos so great their instruments had trouble measuring it. Gamma ray burst GRB 2210099A, which was so bright not only was it named, but it’s what experts believe is also the birth of a black hole.

Space scientists seeking to understand the enigmatic origins of powerful cosmic rays have detected an extremely rare, ultra-high-energy particle that they believe traveled to Earth from beyond the Milky Way galaxy.

The energy of this subatomic particle, invisible to the naked eye, is equivalent to dropping a brick on your toe from waist height, according to the authors of new research published Thursday in the journal Science. It rivals the single most energetic cosmic ray ever observed, the “Oh-My-God” particle that was detected in 1991, the study found.


An artist's illustration of the extremely energetic cosmic ray observed by the Telescope Array Collaboration led by the University of Utah and the University of Tokyo. It's been named the "Amaterasu particle."

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

Cosmic rays are charged particles that travel through space and rain down on Earth constantly. Low-energy cosmic rays can emanate from the sun, but extremely high-energy ones are exceptional. They are thought to travel to Earth from other galaxies and extragalactic sources.

“If you hold out your hand, one (cosmic ray) goes through the palm of your hand every second, but those are really low-energy things,” said study co-author John Matthews, a research professor at the University of Utah.

“When you get out to these really high-energy (cosmic rays), it’s more like one per square kilometer per century. It’s never going through your hand.”

Despite years of research, the exact origins of these high-energy particles still aren’t clear. They are thought to be related to the most energetic phenomena in the universe, such as those involving black holes, gamma-ray bursts and active galactic nuclei, but the biggest discovered so far appear to originate from voids or empty space — where no violent celestial events have taken place.

Tracking high-energy cosmic rays

The recently discovered particle, nicknamed the Amaterasu particle after the sun goddess in Japanese mythology, was spotted by a cosmic ray observatory in Utah’s West Desert known as the Telescope Array.

The Telescope Array, which started operating in 2008, is made up of 507 ping-pong table-size surface detectors covering 270 square miles.

It has observed more than 30 ultra-high-energy cosmic rays but none bigger than the Amaterasu particle, which struck the atmosphere above Utah on May 27, 2021, raining secondary particles to the ground where they were picked up by the detectors, according to the study.

“You can look … (at) how many particles hit each detector and that tells you what the energy of the primary cosmic ray was,” Matthews said.

The event triggered 23 of the surface detectors, with a calculated energy of about 244 exa-electron volts. The “Oh My God particle” detected more than 30 years ago was 320 exa-electron volts.

For reference, 1 exa-electron volt equals 1 billion gigaelectron-volts, and 1 gigaelectron volt is 1 billion electron volts. That would make the Amaterasu particle 244,000,000,000,000,000,000 electron volts. By comparison, the typical energy of an electron in the polar aurora is 40,000 electron volts, according to NASA.

An ultra-high-energy cosmic ray carries tens of millions of times more energy than any human-made particle accelerator such as the Large Hadron Collider, the most powerful accelerator ever built, explained Glennys Farrar, a professor of physics at New York
 University.




“What is required is a region of very high magnetic fields — like a super-sized LHC, but natural. And the conditions required are really exceptional, so the sources are very very rare, and the particles are dissipated into the vast universe, so the chances of one hitting Earth are tiny,” said Farrar, who wasn’t involved in the study, via email.

The atmosphere largely protects humans from any harmful effects from the particles, though cosmic rays sometimes cause computer glitches. The particles, and space radiation more broadly, pose a greater risk to astronauts, with the potential to cause structural damage to DNA and altering many cellular processes, according to NASA,.

Mysterious source

The source of these ultra-high-energy particles baffles scientists.

Matthews, a co-spokesman for the Telescope Array Collaboration, said the two biggest recorded cosmic rays appeared “sort of random” — when their trajectories are traced back, there appears to be nothing high-energy enough to produce such particles. The Amaterasu particle, specifically, seemed to originate from what’s known as the Local Void, an empty area of space bordering the Milky Way galaxy.

“If you take the two highest-energy events — the one that we just found, the ‘Oh-My-God’ particle — those don’t even seem to point to anything. It should be something relatively close. Astronomers with visible telescopes can’t see anything really big and really violent,” Matthews said.

“It comes from a region that looks like a local empty space. It’s a void. So what the heck’s going on?”

An expansion to the Telescope Array may provide some answers. Once completed, 500 new detectors will allow the Telescope Array to capture cosmic ray-induced particle showers across 2,900 square kilometers (about 1,120 square miles) — an area nearly the size of Rhode Island, according to the University of Utah statement.

Extremely energetic cosmic ray detected, but with no obvious source


Peer-Reviewed Publication

AMERICAN ASSOCIATION FOR THE ADVANCEMENT OF SCIENCE (AAAS)



An extremely energetic cosmic ray – an extragalactic particle with an energy exceeding ~240 exa-electron volts (EeV) – has been detected by the Telescope Array experiment’s surface detector, researchers report. However, according to the findings, its arrival direction shows no obvious source. Ultrahigh-energy cosmic rays (UHECRs) are subatomic charged particles from space with energies greater than 1 EeV – roughly a million times as high as the energy reached by human-made particle accelerators. Although low-energy cosmic rays primarily emanate from the sun, the origins of rarer UHECRs are thought to be related to the most energetic phenomena in the Universe, such as those involving black holes, gamma-ray bursts, and active galactic nuclei. Yet much about the physics and acceleration mechanisms of these particles remains unknown. Because arrivals of the most energetic UHECRs are so infrequent – estimated to be less than one particle per century per square kilometer – their detection requires instruments with large collecting areas. Here, members of the Telescope Array Collaboration report the detection of an extremely energetic cosmic ray observed by the Telescope Array (TA) experiment, a surface cosmic-ray detector array located in Utah, USA, that has an effective detection of 700 square kilometers. According to the findings, the unusually high-energy cosmic ray arrived on 27 May 2021 and had a calculated energy of about 244 EeV. Given the particle’s exceptionally high energy, the authors note that it should only experience relatively minor deflections by foreground magnetic fields, and thus, its arrival direction should be expected to be more closely correlated to its source. However, the findings show that its arrival direction shows no obvious source galaxy, or any other known astronomical objects thought to be potential sources of UHECRs. Instead, its arrival direction points back to void in the large-scale structure of the Universe – a region where very few galaxies reside. The authors suggest that this could indicate a much larger magnetic deflection than is predicted by galactic magnetic field models, an unidentified source in the local extragalactic neighborhood, or an incomplete understanding of the associated high-energy particle physics.




No comments: