A new paper details the discovery of the highest-energy light ever observed from the sun.
“The sun is more surprising than we knew,” says Mehr Un Nisa, a postdoctoral research associate at Michigan State University. “We thought we had this star figured out, but that’s not the case.”
Nisa, who will soon be joining Michigan State’s faculty, is the corresponding author of the new paper in the journal Physical Review Letters.
The team behind the discovery also found that this type of light, known as gamma rays, is surprisingly bright. That is, there’s more of it than scientists had previously anticipated.
Although the high-energy light doesn’t reach the Earth’s surface, these gamma rays create telltale signatures that Nisa and her colleagues working with the High-Altitude Water Cherenkov Observatory, or HAWC, detected.
HAWC is an important part of the story. Unlike other observatories, it works around the clock.
“We now have observational techniques that weren’t possible a few years ago,” says Nisa, who works in the Department of Physics and Astronomy in the College of Natural Science.
“In this particular energy regime, other ground-based telescopes couldn’t look at the sun because they only work at night,” she says. “Ours operates 24/7.”
In addition to working differently from conventional telescopes, HAWC looks a lot different from the typical telescope.
Rather than a tube outfitted with glass lenses, HAWC uses a network of 300 large water tanks, each filled with about 200 metric tons of water. The network is nestled between two dormant volcano peaks in Mexico, more than 13,000 feet above sea level.
From this vantage point, it can observe the aftermath of gamma rays striking air in the atmosphere. Such collisions create what are called air showers, which are a bit like particle explosions that are imperceptible to the naked eye.
The energy of the original gamma ray is liberated and redistributed amongst new fragments consisting of lower energy particles and light. It’s these particles—and the new particles they create on their way down—that HAWC can “see.”
When the shower particles interact with water in HAWC’s tanks, they create what’s known as Cherenkov radiation that can be detected with the observatory’s instruments.
Nisa and her colleagues began collecting data in 2015. In 2021, the team had accrued enough data to start examining the sun’s gamma rays with sufficient scrutiny.
“After looking at six years’ worth of data, out popped this excess of gamma rays,” Nisa says. “When we first saw it, we were like, ‘We definitely messed this up. The sun cannot be this bright at these energies.'”
The sun gives off a lot of light spanning a range of energies, but some energies are more abundant than others.
For example, through its nuclear reactions, the sun provides a ton of visible light—that is, the light we see. This form of light carries an energy of about 1 electron volt, which is a handy unit of measure in physics.
The gamma rays that Nisa and her colleagues observed had about 1 trillion electron volts, or 1 tera electron volt, abbreviated 1 TeV. Not only was this energy level surprising, but so was the fact that they were seeing so much of it.
In the 1990s, scientists predicted that the sun could produce gamma rays when high-energy cosmic rays—particles accelerated by a cosmic powerhouse like a black hole or supernova—smash into protons in the sun. But, based on what was known about cosmic rays and the sun, the researchers also hypothesized it would be rare to see these gamma rays reach Earth.
At the time, though, there wasn’t an instrument capable of detecting such high-energy gamma rays and there wouldn’t be for a while. The first observation of gamma rays with energies of more than a billion electron volts came from NASA’s Fermi Gamma-ray Space Telescope in 2011.
Over the next several years, the Fermi mission showed that not only could these rays be very energetic, but also that there were about seven times more of them than scientists had originally expected. And it looked like there were gamma rays left to discover at even higher energies.
When a telescope launches into space, there’s a limit to how big and powerful its detectors can be. The Fermi telescope’s measurements of the sun’s gamma rays maxed out around 200 billion electron volts.
Theorists led by John Beacom and Annika Peter, both professors at Ohio State University, encouraged the HAWC Collaboration to take a look.
“They nudged us and said, ‘We’re not seeing a cutoff. You might be able to see something,” Nisa says.
Now, for the first time, the team has shown that the energies of the sun’s rays extend into the TeV range, up to nearly 10 TeV, which does appear to be the maximum, Nisa says.
Currently, the discovery creates more questions than answers. Solar scientists will now scratch their heads over how exactly these gamma rays achieve such high energies and what role the sun’s magnetic fields play in this phenomenon, Nisa says.
When it comes to the cosmos, though, that’s part of the excitement. It tells us that there was something wrong, missing, or perhaps both when it comes to how we understand our nearest and dearest star.
“This shows that HAWC is adding to our knowledge of our galaxy at the highest energies, and it’s opening up questions about our very own sun,” Nisa says. “It’s making us see things in a different light. Literally.”
The HAWC Collaboration includes more than 30 institutions across North America, Europe, and Asia and has funding from the National Science Foundation and the National Council of Humanities Science and Technology.
Source: Matt Davenport for Michigan State University