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July 9, 2025

New particle acceleration strategy uses cold atoms to unlock cosmic mysteries

(a) Time evolution of the density of the atomic cloud along the x direction according to the non-interacting numerical simulations described in the text. The contour plot is the result of stacking 350 one dimensional density profiles. (b) Same as panel (a) but in momentum space. (c) and (d) report the same time evolutions of panel (a) and (b) respectively, but for numerical simulations accounting for the interatomic interactions. In all panels the color scale has been substantially saturated to better highlight the finer details. Credit: Âé¶¹ÒùÔºical Review Letters (2025). DOI: 10.1103/nrjv-pwy1
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(a) Time evolution of the density of the atomic cloud along the x direction according to the non-interacting numerical simulations described in the text. The contour plot is the result of stacking 350 one dimensional density profiles. (b) Same as panel (a) but in momentum space. (c) and (d) report the same time evolutions of panel (a) and (b) respectively, but for numerical simulations accounting for the interatomic interactions. In all panels the color scale has been substantially saturated to better highlight the finer details. Credit: Âé¶¹ÒùÔºical Review Letters (2025). DOI: 10.1103/nrjv-pwy1

Scientists have used ultracold atoms to successfully demonstrate a novel method of particle acceleration that could unlock a new understanding of how cosmic rays behave, a new study reveals.

More than 70 years after its formulation, researchers have observed the Fermi acceleration mechanism in a laboratory by colliding against engineered movable potential barriers—delivering a significant milestone in high-energy astrophysics and beyond.

Fermi acceleration is the mechanism responsible for the generation of cosmic rays, as postulated by physicist Enrico Fermi in 1949. The process itself also features some universal properties that have spawned a wide range of mathematical models, such as the Fermi-Ulam model. Until now, however, it has been difficult to create a reliable Fermi accelerator on Earth.

Publishing their in Âé¶¹ÒùÔºical Review Letters, the international research team from the Universities of Birmingham and Chicago reveals their success in building a fully controllable Fermi accelerator and using this to observe significant particle acceleration.

The accelerator—just 100 micrometers in size—can quickly accelerate ultracold samples to velocities of more than half a meter per second. It does this by making movable optical potential barriers collide with trapped ultracold atoms.

By combining energy gain and particle losses, the scientists can also obtain energy spectra analogous to those observed in —providing the first direct verification of the so-called Bell's result, which is at the core of every cosmic ray acceleration model.

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Co-author Dr. Amita Deb, from the University of Birmingham, commented, "Results delivered by our Fermi accelerator surpass the best-in-class acceleration methods used in . The technology has the additional advantages of featuring an exceptionally simple and miniaturized setup, and no theoretical upper limits."

The accelerator's generation of ultracold atomic jets demonstrates the potential for high-precision control over particle acceleration. The ability to study Fermi acceleration with cold atoms opens new possibilities for investigating phenomena relevant to high-energy astrophysics.

Future areas of research include the study of particle acceleration at shocks, , and turbulence, which are critical processes in the universe. Studying quantum Fermi acceleration could lead to the development of new tools for manipulating quantum wavepackets, offering promising avenues for advancements in quantum information science.

Dr. Vera Guarrera, one of the leading authors from the University of Birmingham, commented, "Our work represents the first step towards the study of more complex astrophysical mechanisms in the lab. The simplicity and effectiveness of our Fermi accelerator make it a powerful tool for both fundamental research and practical applications in quantum technology."

The research team plans to further explore the applications of their Fermi in various fields, including quantum chemistry and atomtronics. They aim to investigate how different kinds of interactions affect the acceleration rate and the maximum energy attainable, providing valuable insights for both theoretical and experimental physics.

More information: G. Barontini et al, Observation of Fermi acceleration with cold atoms, Âé¶¹ÒùÔºical Review Letters (2025).

Journal information: Âé¶¹ÒùÔºical Review Letters

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A laboratory-scale Fermi accelerator using ultracold atoms and movable optical barriers has achieved controlled particle acceleration, directly verifying key cosmic ray acceleration models such as Bell's result. This compact system enables precise studies of high-energy astrophysical processes and offers new opportunities for quantum technology and fundamental physics research.

This summary was automatically generated using LLM.