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• Building block for a better understanding of the universe
• New insights into the fundamental force of “strong interaction”
• Publication in the leading journal Nature
Another long-standing mystery in particle physics has finally been solved. An international research team of the ALICE experiment at CERN’s particle accelerator, led by researchers from the Technical University of Munich (TUM), has for the first time directly observed how light atomic nuclei and their antiparticles – so-called deuterons and antideuterons – are formed in extremely high-energy particle collisions.
The result: The protons and neutrons necessary for the formation of deuterons are released during the decay of very short-lived, highly energetic particle states (so-called resonances) and then bind together. The same holds true for their antimatter counterparts. The findings were published in the renowned journal Nature.
In proton collisions at the Large Hadron Collider (LHC) at CERN, temperatures arise that are more than 100,000 times hotter than the center of the Sun. Until now, it had been entirely unclear how fragile particles such as deuterons and antideuterons could survive under these conditions. In such an environment, light atomic nuclei like the deuteron – consisting of just one proton and one neutron – should in fact disintegrate immediately, since the binding force that holds them together is comparatively weak. Yet such nuclei had repeatedly been observed. It is now clear: about 90 percent of the observed (anti)deuterons are produced through this mechanism.
Better understanding of the universe
TUM particle physicist Prof. Laura Fabbietti, a researcher in the ORIGINS Cluster of Excellence and SFB1258, emphasizes: “Our result is an important step toward a better understanding of the ‘strong interaction’ – that fundamental force that binds protons and neutrons together in the atomic nucleus. The measurements clearly show: light nuclei do not form in the hot initial stage of the collision, but later, when the conditions have become somewhat cooler and calmer.”
Dr. Maximilian Mahlein, a researcher at Fabbietti’s Chair for Dense and Strange Hadronic Matter at the TUM School of Natural Sciences, explains: “Our discovery is significant not only for fundamental nuclear physics research. Light atomic nuclei also form in the cosmos – for example in interactions of cosmic rays. They could even provide clues about the still-mysterious dark matter. With our new findings, models of how these particles are formed can be improved and cosmic data interpreted more reliably.”
Further information:
CERN (Conseil Européen pour la Recherche Nucléaire) is the world’s largest research center for particle physics. It is located on the border between Switzerland and France near Geneva. Its centerpiece is the LHC, a 27-kilometer-long underground ring accelerator. In it, protons collide at nearly the speed of light. These collisions recreate conditions similar to those that existed just after the Big Bang – temperatures and energies that do not occur anywhere in everyday life. Researchers can thus investigate how matter is structured at its most fundamental level and which natural laws apply there.
Among the experiments at the LHC, ALICE (A Large Ion Collider Experiment) is specifically designed to study the properties of the so-called strong interaction – the force that holds protons and neutrons together in atomic nuclei. ALICE acts like a giant camera, capable of precisely tracking and reconstructing up to 2000 particles created in each collision. The aim is to reconstruct the conditions of the universe’s earliest fractions of a second – and thereby better understand how a soup of quarks and gluons first gave rise to stable atomic nuclei and ultimately to matter.
The ORIGINS Cluster of Excellence investigates the formation and evolution of the universe and its structures – from galaxies, stars, and planets to the very building blocks of life. ORIGINS traces the path from the smallest particles in the early universe to the emergence of biological systems. Examples include the search for conditions that could enable extraterrestrial life and a deeper understanding of dark matter. In May 2025, the second funding phase of the cluster, jointly proposed by TUM and Ludwig-Maximilians-Universität München (LMU), was approved as part of the highly competitive Excellence Strategy of the German federal and state governments.
The Collaborative Research Center “Neutrinos and Dark Matter in Astro- and Particle Physics” (SFB 1258) focuses on fundamental physics, where the weak interaction, one of the four fundamental forces of nature, is central. The third funding period of the SFB1258 started in January 2025.
Additional material for media outlets:
Photos for download:
https://mediatum.ub.tum.de/1838626
https://mediatum.ub.tum.de/1838627
Press release on tum.de
Prof. Dr. Laura Fabbietti
Technical University of Munich
TUM School of Natural Sciences
Professorship for Experimental Physiks - Dense and Strange Hadronic Matter
laura.fabbietti@ph.tum.de
ALICE Collaboration, M. Mahlein, L. Fabbietti et al. Observation of deuteron and antideuteron formation from resonance-decay nucleons, published in Nature 648, pages 306–311 (2025), https://doi.org/10.1038/s41586-025-09775-5
Schematic artistic imaging of the formation of deuterons
Quelle: ALICE / TUM
Copyright: ALICE / TUM
Prof. Dr. Laura Fabbietti, TUM School of Natural Sciences, Professur für Experimentalphysik
Quelle: Astrid Eckert / TUM
Copyright: Astrid Eckert / TUM
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Schematic artistic imaging of the formation of deuterons
Quelle: ALICE / TUM
Copyright: ALICE / TUM
Prof. Dr. Laura Fabbietti, TUM School of Natural Sciences, Professur für Experimentalphysik
Quelle: Astrid Eckert / TUM
Copyright: Astrid Eckert / TUM
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