• 12/13/2022
  • Reading time 2 min.

New findings lay the foundation for the search for dark matter

Antihelium nuclei as messengers from the depths of the galaxy

How are galaxies born, and what holds them together? Astronomers assume that dark matter plays an essential role. However, as yet it has not been possible to prove directly that dark matter exists. A research team including Technical University of Munich (TUM) scientists has now measured for the first time the survival rate of antihelium nuclei from the depths of the galaxy – a necessary prerequisite for the indirect search for Dark Matter.

Prof. Dr. Laura Fabbietti (right) discusses the experiments on the antihelium-3 interaction with Laura Šerkšnytė (center) and Stephan Königstorfer. Astrid Eckert / TUM
Prof. Dr. Laura Fabbietti (right) discusses the experiments on the antihelium-3 interaction with Laura Šerkšnytė (center) and Stephan Königstorfer.

Many things point to the existence of dark matter. The way in which galaxies move in galactic clusters, or how fast stars circle the center of a galaxy results in calculations which indicate that there must be far more mass present than what we can see. Approximately 85 percent of our Milky Way for example consists of a substance which is not visible and which can only be detected based on its gravitational effects. As of today it has still not been possible to directly prove the existence of this material.

Several theoretical models of dark matter predict that it could be composed of particles which interact weakly with one another. This produces antihelium-3 nuclei, which consist of two antiprotons and one antineutron. These nuclei are also generated in high-energy collisions between cosmic radiation and common matter like hydrogen and helium – however, with energies different from those that would be expected in the interaction of dark matter particles.

In both processes, the antiparticles originate in the depths of the galaxy, several tens of thousands of lightyears away from us. After their creation, a part of them makes its way in our direction. How many of these particles survive this journey unscathed and reach the vicinity of the Earth as messengers of their formation process determines the transparency of the Milky Way for antihelium nuclei. Until now scientists have only been able to roughly estimate this value. However, an improved approximation of transparency, a unit of measure for the number and energies of antinuclei, will be important for interpreting future antihelium measurements.

LHC particle accelerator as antimatter factory

Researchers from the ALICE collaboration have now carried out measurements that have enabled them to determine the transparency more precisely for the first time. ALICE stands for A Large Ion Collider Experiment and is one of the largest experiments in the world to explore physics on the smallest length scales. ALICE is part of the Large Hadron Collider (LHC) at CERN.

The LHC can generate large amounts of light antinuclei such as antihelium. To do so, protons and lead atoms are each put on a collision course. The collisions produce particle showers which are then recorded by the detector of the ALICE experiment. Thanks to several subsystems of the detector, the researchers can then detect the antihelium-3 nuclei that have formed and follow their trails in the detector material. This makes it possible to quantify the probability that an antihelium-3 nucleus will interact with the detector material and disappear. Scientists from TUM and the Excellence Cluster ORIGINS have contributed significantly to the analysis of the experimental data.

Artistic illustration of antihelium annihilation in the  ALICE detector at CERN as well as in the universe. ORIGINS Cluster/S. Kwauka
Artistic illustration of antihelium annihilation in the ALICE detector at CERN as well as in the universe.

Galaxy transparent for antinuclei

Using simulations, the researchers were able to transfer the findings from the ALICE experiment to the entire galaxy. The result: About half of the antihelium-3 nuclei which were expected to be generated in the interaction of dark matter particles would reach the vicinity of the Earth. Our Milky Way is thus 50 percent permeable for these antinuclei. For antinuclei generated in collisions between cosmic radiation and the interstellar medium, the resulting transparency varies from 25 to 90 percent with increasing antihelium-3 momentum. However, these antinuclei can be distinguished from those generated from dark matter based on their higher energy.

This means that antihelium nuclei can not only travel long distances in the Milky Way, but also serve as important informants in future experiments: Depending on how many antinuclei arrive at the Earth and with which energies, the origin of these well-travelled messengers can be interpreted as cosmic rays or dark matter thanks to the new calculations.

Reference for future antinuclei measurements in space

"This is an excellent example of an interdisciplinary analysis that illustrates how measurements at particle accelerators can be directly linked with the study of cosmic rays in space," says ORIGINS scientist Prof. Laura Fabbietti of the TUM School of Natural Sciences. The results from the ALICE experiment at the LHC are of great importance for the search for antimatter in space with the AMS-02 module (Alpha Magnetic Spectrometer) on the International Space Station (ISS). Starting in 2025 the GAPS balloon experiment over the Arctic will also examine incoming cosmic rays for antihelium-3.

 

Video: The first measurement of the Anti-3He absorption in matter (Credit: CERN)

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Publications

The ALICE Collaboration. Measurement of anti-3He nuclei absorption in matter and impact on their propagation in the Galaxy. Nat. Phys. (2022).
doi.org/10.1038/s41567-022-01804-8

Further information and links
  • Images for editorial use
  • The work on the antihelium-3 interaction, led by Prof. Dr. Laura Fabbietti, involved research groups led by Prof. Dr. Alejandro Ibarra at TUM and Dr. Andrew Strong at the Max Planck Institute for Extraterrestrial Physics. This research has been funded by the Federal Ministry of Education and Research, and also by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) through the Excellence Cluster ORIGINS, EXC 2094 - 390783311 and the Collaborative Research Center SFB1258.

Technical University of Munich

Corporate Communications Center

Contacts to this article:

Prof. Laura Fabbietti
Technical University of Munich
Professorship of Experimentalphysik - Dense and Strange Hadronic Matter
Excellence Cluster ORIGINS (Connector Coordinator)
laura.fabbietti@ph.tum.de
+ 49 (89) 289 - 12433

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