Study led by UW–Madison researcher confirms star wreck as source of extreme cosmic particles

Astronomers have long sought the launch sites for some of the highest energy protons in our galaxy. Now, a study using 12 years of data from NASA’s Fermi Gamma-ray Space Telescope (Fermi) confirms that a remnant of a supernova, or star explosion, is just such a place, solving a decade-long cosmic mystery. 

Previously, Fermi has shown that the shock waves of exploded stars boost particles to speeds comparable to that of light. Called cosmic rays, these particles mostly take the form of protons, but can include atomic nuclei and electrons. Because they all carry an electric charge, their paths become scrambled as they whisk through our galaxy’s magnetic field, which masks their origins. But when these particles collide with interstellar gas near the supernova remnant (SNR), they produce a telltale glow in gamma rays—the highest-energy light there is.

A picture of Ke Fang, assistant professor in the Department of Physics at the University of Wisconsin–Madison.
Ke Fang, assistant professor in the Department of Physics at the University of Wisconsin–Madison.

“Theorists think the highest energy cosmic ray protons in the Milky Way reach a million billion electron volts, or PeV energies,” said Ke Fang, an assistant professor of physics at the Wisconsin IceCube Particle Astrophysics Center (WIPAC), a research center at the University of Wisconsin–Madison. “The precise nature of their sources, which we call PeVatrons, has been difficult to pin down.” 

Fang, who led the study, performed the data analysis and developed the theory models. The research team identified a few suspected PeVatrons, including one at the center of our galaxy. Naturally, SNR top the list of candidates. Yet out of about 300 known remnants, only a few have been found to emit gamma rays with sufficiently high energies. 

One particular star wreck has commanded a lot of attention from gamma-ray astronomers. Called G106.3+2.7, it is a comet-shaped cloud located about 2,600 light-years away in the constellation Cepheus. A bright pulsar caps the northern end of the SNR, and astronomers think both objects formed in the same explosion.

An image showing a newly discovered PeVatron (in pink) hosted by a supernova remnant (in green) called G106.3+2.7. The supernova remnant is believed to have formed together with the pulsar (in magenta) about 10,000 years ago. Particles accelerated by the shock waves of the supernova remnant interact with the gas in the interstellar medium, producing high-energy gamma-ray emission. Credit: Jayanne English, University of Manitoba, NASA/Fermi/Fang et al. 2022, and Canadian Galactic Plane Survey/DRAO.
The newly discovered PeVatron (in pink) is hosted by a supernova remnant (in green) called G106.3+2.7. The supernova remnant is believed to have formed together with the pulsar (in magenta) about 10,000 years ago. Particles accelerated by the shock waves of the supernova remnant interact with the gas in the interstellar medium, producing high-energy gamma-ray emission. Credit: Jayanne English, University of Manitoba, NASA/Fermi/Fang et al. 2022, and Canadian Galactic Plane Survey/DRAO.

“SNR are leading candidates due to their efficient diffusive shock acceleration. However, only a couple SNR have been observed above 1 TeV,” said Fang. “Our work provides observational evidence for one of them as a PeVatron.”

A paper detailing the findings was published today in the journal Physical Review Letters. The paper also received the Editor’s Suggestion, which “direct readers to interesting, important, and well-written Letters in areas of research beyond their usual interests.”

Fermi’s Large Area Telescope (LAT), its primary instrument, detected billion-electron-volt (GeV) gamma rays from within the remnant’s extended tail; for comparison, visible light’s energy measures between about 2 and 3 electron volts. The Very Energetic Radiation Imaging Telescope Array System (VERITAS) at the Fred Lawrence Whipple Observatory in southern Arizona recorded even higher-energy gamma rays from the same region. And both the High-Altitude Water Cherenkov Gamma-Ray Observatory in Mexico and the Tibet AS-Gamma facility in China have detected photons with energies of 100 trillion electron volts (TeV) from the area probed by Fermi and VERITAS.

The pulsar, J2229+6114, emits its own gamma rays in a lighthouse-like beacon as it spins, and this glow dominates the region to energies of a few GeV. Most of this emission occurs in the first half of the pulsar’s rotation. The team effectively turned off the pulsar by analyzing only gamma rays arriving from the latter part of the cycle. Below 10 GeV, there is no significant emission from the remnant’s tail.

A gif showing a sequence comparing Fermi results in three energy ranges. Pulsar J2229+6114 is the brilliant source at the northern tip of supernova remnant G106.3+2.7 (outlined in green). In each range, the sequence first shows the number of gamma rays, and then the amount of excess signal compared with expectations from a model of the background. Brighter colors indicate greater numbers of gamma rays or excess amount. At the highest energies, a new source of gamma rays emerges, produced when protons accelerated by the supernova’s shock wave strike a nearby gas cloud.
This sequence compares Fermi results in three energy ranges. Pulsar J2229+6114 is the brilliant source at the northern tip of supernova remnant G106.3+2.7 (outlined in green). In each range, the sequence first shows the number of gamma rays, and then the amount of excess signal compared with expectations from a model of the background. Brighter colors indicate greater numbers of gamma rays or excess amount. At the highest energies, a new source of gamma rays emerges, produced when protons accelerated by the supernova’s shock wave strike a nearby gas cloud. Credit: NASA/Fermi/Fang et al. 2022

Above this energy, the pulsar’s interference is negligible and the additional source becomes readily apparent. The team’s detailed analysis overwhelmingly favors PeV protons as the particles driving this gamma-ray emission.

“So far, G106.3+2.7 is unique, but it may turn out to be the brightest member of a new population of SNR that emit gamma rays reaching TeV energies,” notes Fang, a member of the Fermi LAT scientific collaboration. “More of them may be revealed through future observations by Fermi and very-high-energy gamma-ray observatories.”

Explore how astronomers located a supernova remnant that fires up protons to energies 10 times greater than the most powerful particle accelerator on Earth. Credit: NASA’s Goddard Space Flight Center

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This study was a joint effort with coauthors and Fermi LAT collaboration members Matthew Kerr, Roger Blandford, Henrike Fleischhack, and Eric Charles.

The Fermi LAT scientific collaboration currently includes more than 400 scientists and students at more than 90 universities and laboratories in 12 countries.

The Fermi Gamma-ray Space Telescope is an astrophysics and particle physics partnership managed by NASA’s Goddard Space Flight Center. Fermi was developed in collaboration with the U.S. Department of Energy, with important contributions from academic institutions and partners in France, Germany, Italy, Japan, Sweden, and the United States.

Click here for the NASA press release.