High above Earth, in the thin air of the Tibetan Plateau, a giant observatory has caught the universe doing something it shouldn’t be able to do.

The Large High Altitude Air Shower Observatory (LHAASO) has detected ultra-powerful gamma rays—reaching energies of about one quadrillion electron volts (PeV)—coming from a seemingly ordinary stellar remnant. 

The source is a pulsar wind nebula (PWN) powered by the pulsar PSR J1849-0001, located in the constellation Aquila. “Pulsar wind nebulae (PWNe) are bubbles of relativistic particles, powered by the rotational energy loss of the central pulsars,” the study authors note.

What makes this discovery remarkable is not just the energy, but the efficiency. This system appears to convert energy into high-speed particles far more effectively than current physics says it should. 

In simple terms, astronomers may have found a cosmic particle accelerator that outperforms even their best theoretical designs

Weaker than Crab, but still more powerful 

To understand the breakthrough, it helps to know what scientists were looking at. A pulsar wind nebula forms when a dead star, called a pulsar, spins rapidly and blasts out a stream of charged particles at nearly the speed of light. 

When this wind crashes into surrounding material, it creates a glowing, energetic cloud. The most famous example is the Crab Nebula, long considered a benchmark for extreme particle acceleration.

“The Crab Nebula, powered by the Milky Way’s most energetic pulsar, was discovered by the Large High Altitude Air Shower Observatory (LHAASO) as a PeV gamma-ray emitter, thereby establishing it as an extreme particle accelerator along with multiwavelength observations,” the study authors explained.

However, PSR J1849-0001 is no Crab. Its energy output is about 50 times weaker. According to standard theories, that should mean a much dimmer and less energetic nebula. Instead, LHAASO’s detectors told a very different story.

The observatory works by tracking cascades of particles—called air showers—that form when high-energy gamma rays strike Earth’s atmosphere. By reconstructing these showers, scientists can estimate the energy and origin of the incoming gamma rays. 

Using this method, the team found that the nebula around PSR J1849-0001 emits gamma rays following a power-law spectrum extending up to 2 PeV—an extreme range rarely seen.

Even more surprising, the nebula’s gamma-ray luminosity at PeV energies is several times higher than that of the Crab Nebula, despite its weaker pulsar. This immediately raised a red flag: how can a less powerful engine produce a stronger high-energy output?

Decoding the Aquila Booster

To dig deeper, the researchers combined LHAASO data with X-ray observations to map the nebula’s internal conditions—things like magnetic fields and particle densities. 

This multi-wavelength approach allowed them to estimate how efficiently the system accelerates particles. The result was eye-opening. The nebula operates at at least 27 percent of the theoretical efficiency limit under ideal magnetohydrodynamic conditions.  

This is higher than the Crab’s already impressive ~16 percent. Due to this unexpected performance, the team nicknamed the system the Aquila Booster.

“Combined X-ray observations reveal an extreme particle acceleration efficiency approaching or even exceeding unity in the PWN, which we refer to as the ‘Aquila Booster,’ the study authors said.

However, here’s where things get tricky. In the standard picture, particles gain energy at a termination shock, where the pulsar wind slams into surrounding material. 

If that mechanism were responsible here, the required efficiency would exceed 100 percent, which is physically impossible. In other words, the observed energies simply cannot be explained by the conventional model. 

Something else must be accelerating these particles, but scientists don’t yet know what.

Not the full and final outcome

This discovery exposes a gap in our understanding of how the universe works. If a relatively modest pulsar system can outperform theoretical limits, then the physics of particle acceleration in extreme environments needs revision. 

It suggests that pulsar wind nebulae as a class may be far more efficient—and more common sources of ultra-high-energy cosmic rays than previously thought.

However, the efficiency estimates depend on models of the nebula’s internal structure. Future observations, especially across more wavelengths and with next-generation detectors, will be crucial to confirm whether this behavior is typical or a rare exception.

The study is published in the journal Nature Astronomy.