Near-miss particle encounters reveal hidden secrets of strong force

Deep inside every atom lies a restless world of quarks and gluons—the tiny building blocks that hold everything together, from rocks to stars. For decades, physicists have tried to understand how these particles behave, especially under extreme conditions. 

“We need to know how these gluons behave in these extreme conditions because gluons keep the universe together. And at this point, photonuclear interactions are the best way we have to study gluon behavior,” Gian Michele Innocenti, an experimental physicist and an assistant professor at MIT, said.

Now, using the Large Hadron Collider (LHC), Innocenti and his team have found a new way to peer into this hidden world—not through violent crashes, but through near-misses. Instead of smashing particles head-on, they focused on moments when particles just barely skim past each other. 

These fleeting encounters, once dismissed as background noise, have now revealed new behavior in the strong nuclear force—the fundamental force that binds matter together. This discovery could change how scientists study nuclear matter and open a new path to understanding the universe at its most basic level.

The rare and ignored events

Particle accelerators like the LHC typically work by firing beams of particles at nearly the speed of light and smashing them together. These collisions create showers of smaller particles, which scientists analyze to reconstruct what lies inside atoms.

However, there’s a complication. Alongside these head-on collisions, particles also produce a constant stream of near-miss events. When fast-moving particles pass close to each other, they are surrounded by flattened electromagnetic fields—like invisible pancakes of energy. These fields generate extremely energetic photons (particles of light).

Occasionally, one of these photons strikes a nearby atomic nucleus. This interaction is called a photonuclear interaction. For years, scientists ignored these events because they were rare and buried in massive amounts of collision data.

“These photonuclear events were considered a background that people wanted to cancel,” Innocenti says. The MIT team decided to do the opposite—they treated these near-misses as signals rather than noise.

Turning missed collisions into a powerful microscope

To make this work, the researchers first simulated what these photonuclear events should look like. They focused on a very specific outcome: the production of a D0 meson, a particle that contains a rare charm quark. 

Charm quarks don’t normally exist inside everyday matter and only appear in high-energy conditions, making them excellent tools for probing the nuclear interior. Next, the team developed a special algorithm that could scan billions of particle collisions in real time and pick out the few rare cases where a photon hit a nucleus and produced a D0 meson. 

They implemented this system in the Compact Muon Solenoid (CMS) detector, one of the largest detectors at the collider. However, even with such a highly advanced detector, picking the rare missed events was a very tough task.

“We had to collect tens of billions of collisions in order to extract a few hundred of these rare instances where a photon hits a nucleus and produces one of these exotic D0 meson particles,” Innocenti said. 

By studying the energy, direction, and number of D0 mesons produced, the researchers could work backward to estimate how gluons, the particles that glue quarks together, are distributed inside the nucleus.

What they found was surprising. When nuclear matter is packed tightly and moving at extreme speeds, gluons begin to behave in unusual ways. This confirms long-standing predictions about high-density nuclear matter, but more importantly, it proves that this new method can actually measure such effects.

In simple terms, the team turned what used to be ignored background noise into a kind of ultra-precise microscope—one that uses light itself to probe the heart of matter.

Tiny particles, big breakthrough

This study has wide implications for physics. For instance, understanding how gluons behave is essential because they govern the strong force. A clearer picture of this force could improve theories that describe everything from nuclear reactions to the early universe just after the Big Bang.

“The description of the strong force is at the basis of everything we see in nature. Now we have a way to either fully confirm or show deviations from that description,” Innocenti added.

The method also offers a cleaner and more precise way to study nuclear structure compared to traditional collision-based approaches. By using photonuclear interactions, scientists can probe matter without the chaos of full particle collisions.

However, there are still limitations. These events are extremely rare, requiring massive datasets and highly refined detection techniques. The current measurements are still not precise enough to fully map the behavior of gluons under all conditions.

This is exactly what researchers plan to do next. By improving their algorithms and collecting more data, the team hopes to improve their measurements and possibly uncover deviations from existing theories. If such deviations are found, they could point to new physics beyond what scientists currently understand.

The study is published in the journal Physical Review Letters.