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Quantum sensors are redefining how physicists detect particles in high-speed collisions, enabling precision in both space and time. This leap could uncover new, exotic forms of matter. Credit: SciTechDaily.com
Physicists are tapping into the strange world of quantum sensors to revolutionize particle detection in the next generation of high-energy experiments.
These new superconducting detectors not only offer sharper spatial resolution but can also track events in time—essential for decoding chaotic particle collisions. By harnessing cutting-edge quantum technologies originally developed for astronomy and networking, researchers are making huge strides toward identifying previously undetectable particles, including potential components of dark matter.
Unlocking the Universe With Particle Colliders
To better understand the fundamental nature of matter, energy, space, and time, physicists use powerful machines called particle accelerators. These machines collide high-energy particles, creating bursts of millions of new particles, each with different masses and speeds, every second. Sometimes, these collisions even produce particles that don’t fit within the Standard Model, the leading theory that explains the basic building blocks of the universe.
Now, researchers are planning to build even more powerful accelerators, capable of generating even more intense collisions. But with all that complexity, how can scientists sort through the resulting subatomic chaos?
The SMSPDs can precisely detect single particles at a time. The detectors were designed and fabricated at JPL and commissioned at the INQNET-Caltech labs. Credit: Cristián Peña, Fermilab
Quantum Sensors: A Precision Breakthrough
The key may be quantum sensors. Scientists at the U.S. Department of Energy’s Fermilab, Caltech, NASA’s Jet Propulsion Laboratory (JPL), and other institutions are developing a new kind of particle detection system that uses quantum sensors, extra-sensitive devices that can detect individual particles with high precision.
“In the next 20 to 30 years, we will see a paradigm shift in particle colliders as they become more powerful in energy and intensity,” says Maria Spiropulu, the Shang-Yi Ch’en Professor of Physics at Caltech. “And that means we need more precise detectors. This is why we are developing the quantum technology today. We want to include quantum sensing in our toolbox to optimize next-generation searches for new particles and dark matter, and to study the origins of space and time.”
First Real-World Test of Quantum Detectors
Reporting in the Journal of Instrumentation, the research team, which also includes collaborators at the University of Geneva and Federico Santa María Technical University in Chile, tested its new technology, called superconducting microwire single-photon detectors (SMSPDs), for the first time at Fermilab near Chicago. They exposed the quantum sensors to high-energy beams of protons, electrons, and pions, and demonstrated that the sensors were highly efficient at detecting the particles with improved time and spatial resolution compared to traditional detectors.
This is a significant step toward developing advanced detectors for future particle physics experiments, says co-author Si Xie, a scientist at Fermilab who has a joint appointment at Caltech as a research scientist. “This is just the beginning,” he says. “We have the potential to detect particles lower in mass than we could before as well as exotic particles like those that may constitute dark matter.”
Origins in Astronomy and Quantum Networks
The quantum sensors used in the study are similar to a related family of sensors (called superconducting nanowire single-photon detectors, or SNSPDs), which have applications in quantum networks and astronomy experiments. For example, researchers at JPL—who are among the world’s top experts at designing and fabricating these sensors—recently used them in the Deep Space Optical Communications experiment, a technology demonstration that used lasers to transmit high-definition data from space to the ground.
Spiropulu, Xie, and other scientists from Fermilab, Caltech, and JPL have also used the SNSPD sensors in quantum networking experiments, in which they teleported information across long distances—an important step in developing a quantum internet in the future. That program, called Intelligent Quantum Networks and Technologies (INQNET), was jointly founded in 2017 by Caltech and AT&T.
The experimental setup for studying SMSPDs at the Fermilab Test Beam Facility. A silicon telescope tracks the position of each particle incident. The SMSPD is placed between the telescope’s six strip modules on one side and four pixels plus an additional six strip modules on the other. The modules are placed as close to the cryostat as possible. Credit: Christina Wang, Fermilab
New Capabilities for Particle Physics
For the particle physics tests, the researchers used SMSPDs rather than the SNSPDs, because they have a larger surface area for collecting the sprays of particles. They used the sensors to detect charged particles for the first time, an ability that is not needed for quantum networks or astronomy applications but is essential for particle physics experiments. “The novelty of this study is that we proved the sensors can efficiently detect charged particles,” Xie says.
The SMSPD sensors can also more precisely detect particles in both space and time. “We call them 4D sensors because they can achieve better spatial and time resolution all at once,” Xie says. “Normally in particle physics experiments, you have to tune the sensors to have either more precise time or spatial resolution but not both simultaneously.”
Why 4D Matters in Particle Tracking
When researchers analyze the bunches of particles that fly out of high-speed collisions, they want to be able to precisely trace their paths in space and time. As an analogy, imagine you want to use security images to track a suspicious person hiding in a crowd of people flooding into Grand Central Station from various trains. You would want the images to have enough spatial resolution to track individuals. But you would also want enough time resolution to make sure you catch your person of interest. If you can only obtain images taken every 10 seconds, you might miss the person, but if you have pictures captured every second, you will have better odds.
“In these collisions, you might want to track the performance of millions of events per second,” Spiropulu says. “You are swamped with hundreds of interactions, and it can be hard to find the primary interactions with precision. Back in the 1980s, we thought having the spatial coordinates were enough, but now, as the particle collisions become more intense, producing more particles, we also need to track time.”
The multi-institutional research team that used SMSPDs to efficiently detect high-energy particles. Pictured, front row (left to right): Cristián Peña, Artur Apresyan, and Si Xie; middle row: Carlos Perez, Christina Wang, and Adi Bornheim; back row: Aram, Matias Barria, Valentina Vega, and Claudio San Martin. Credit: Cristián Peña, Fermilab
Paving the Way for Future Colliders
“We are very excited to work on cutting-edge detector R&D like SMSPDs because they may play a vital role in capstone projects in the field, such as the planned Future Circular Collider or a muon collider, says Fermilab scientist and Caltech alumnus Cristián Peña (PhD ’17), who led the research. “And we are thrilled to have assembled a world-class team across several institutions to push this emerging research to the next level.”
Reference: “High energy particle detection with large area superconducting microwire array” by Cristián Peña, Christina Wang, Si Xie, Adolf Bornheim, Matías Barría, Claudio San Martín, Valentina Vega, Artur Apresyan, Emanuel Knehr, Boris Korzh, Jamie Luskin, Lautaro Narváez, Sahil Patel, Matthew Shaw and Maria Spiropulu, 4 March 2025, Journal of Instrumentation.
DOI: 10.1088/1748-0221/20/03/P03001
The study was funded by the US Department of Energy, Fermilab, the National Agency for Research and Development (ANID) in Chile, and the Federico Santa María Technical University. Other Caltech authors include former graduate student Christina Wang (PhD ’24), research scientist Adi Bornheim, postdoc Andrew Mueller (PhD ’24), and graduate student Sahil Patel (MS ’22). Other JPL authors are Boris Korzh (now a professor at the University of Geneva), Jamie Luskin, and Matthew Shaw.
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