The international research collaboration BASE, including QuantumFrontiers scientists from Leibniz Universität Hannover (LUH) and the Physikalisch-Technische Bundesanstalt Braunschweig, has successfully relocated protons outside of an antimatter laboratory for the first time. The consortium, led by Heinrich Heine University Düsseldorf (HHU), developed an autonomous and open ‘Penning trap’ for this purpose. This breakthrough marks a significant step toward transporting antiprotons produced at the European Organisation for Nuclear Research (CERN) to high-precision laboratories, for example in Hanover, Braunschweig and Düsseldorf. This is because extremely precise measurements to compare matter and antimatter are only possible far from accelerator facilities, as the researchers now explain in the scientific journal Nature.
Protons are the basic building blocks of matter. Together with neutrons, they form atomic nuclei. These minute, positively charged particles have an antimatter counterpart, antiprotons. While the latter have a negative charge and a reversed magnetic moment, they are otherwise identical to protons – at least according to the Standard Model of particle physics.
The BASE collaboration (Baryon Antibaryon Symmetry Experiment based at CERN in Geneva is searching for minuscule differences between protons and antiprotons. Professor Dr Stefan Ulmer, physicist at HHU and the founder and spokesperson of the BASE collaboration, explains: “We need an extremely high level of measuring accuracy to be able to identify possible differences in the magnetic moment or charge-to-mass ratio. It is virtually impossible to achieve this close to CERN’s accelerators, though, as the magnetic disturbance that the accelerators there generate is simply too high. Accordingly, we want to bring antiprotons produced at CERN to Düsseldorf and other cities to measure them in extremely well shielded laboratories.”
High-precision measurements of this kind require low-energy antiprotons, which can only be produced at CERN. Specifically, in the Antimatter Factory (AMF) at the Antiproton Decelerator (AD) where the experiment is based. The antiprotons have already successfully been decelerated and confined in a so-called Penning trap.
Relocating the antiprotons to another laboratory that is many hundreds of kilometres away is a highly complex task. The BASE team has taken a decisive step in this regard by developing a robust, transportable, superconducting, open and autonomous Penning-trap system known as BASE-STEP. This system allows antiprotons to be injected and ejected from the trap, and thus transferred to other experiments. They used it for the first time in autumn 2024 to extract a proton cloud from the AMF and transport it by truck across CERN’s main site.
Marcel Leonhardt, a master’s student of Professor Ulmer and lead author of the publication: “We were able to demonstrate the loss-free relocation of protons, sustain autonomous operation without external power for four hours and continue to operate the trap loss-free afterwards. An important step that shows that particles can thus be relocated over longer distances in normal road traffic.”
Dr Christian Smorra from HHU, BASE-STEP Project Leader and senior scientist in BASE adds: “Mobile power generators can be used to increase the transport range of the system at will, enabling longer transport routes and times. Our vision is to be able to reach laboratories across Europe in the future.”
Now that the transport system’s functionality has been proven with protons, the next step is to tackle the relocation of antiprotons. Smorra: “If we also manage this, then it will mark the potential rise of a new era in antimatter precision research. We could then perform antiproton spectroscopy in the most suitable laboratories in the future.”
At Leibniz Universität Hannover, the BASE collaboration operates a Penning trap laboratory that could receive antiprotons from CERN via BASE-STEP. “The proton transport results of BASE-STEP are really exciting”, emphasizes Prof. Dr. Christian Ospelkaus, who leads the BASE team at Leibniz Universität Hannover and PTB together with Dr. Juan Manuel Cornejo. “The success of BASE-STEP brings us one step closer to receiving antiprotons from CERN’s AD facility. In our lab, we develop methods, borrowed from quantum computers and atomic clocks, with the aim to support the highest possible accuracies in antiproton precision measurements.”
Background:
High-precision experiments on CPT invariance With antiprotons as basic constituents of antimatter, stringent matter-antimatter comparisons are possible. The underlying question is whether matter and antimatter differ in characteristics such as mass, charge and magnetic moment. According to the Standard Model of particle physics, there should not be any differences. However, the genesis of matter after the Big Bang suggests that differences must in fact exist.
Among other things, the researchers sought to test the fundamental charge-parity-time (CPT) reversal invariance in the Standard Model of particle physics. This states that any process that arises from another possible process by swapping matter with antimatter and additionally mirroring space and reversing time also complies with the laws of physics and is thus possible.
Low-energy antiprotons were used at the AMF to perform such tests in the high-precision spectroscopy of antiprotonic atoms (atoms in which the electron has been replaced by an antiproton) and antihydrogen. When comparing the magnetic moments of protons and antiprotons, BASE has so far achieved a precision of 1.5 parts per billion.
The collaboration also achieved the most precise test of CPT invariance to date for baryons (heavy particles usually consisting of three quarks, including the proton and antiproton) by comparing their charge-to-mass ratio. A relative uncertainty of 16 parts per trillion was achieved.
About the BASE collaboration
Established in 2013 and based at the Antimatter Factory (AMF) at CERN, research institutes in Germany, Japan, the United Kingdom and Switzerland are involved in the collaboration. These include: CERN – European Organisation for Nuclear Research, Geneva, Switzerland; ETH – Eidgenössische Technische Hochschule, Zürich, Switzerland; GSI Helmholtzzentrum für Schwerionenforschung GmbH, Darmstadt, Germany; HHU – Heinrich Heine University Düsseldorf, Germany; ICL – Imperial College London, UK; JGU – Johannes Gutenberg University Mainz, Germany; LUH – Leibniz University Hannover, Germany; MPIK – Max Planck Institute for Nuclear Physics, Heidelberg, Germany; PTB – National Metrology Institute of Germany (PTB) , Germany; RIKEN, Institute for Physical and Chemical Research, Wako, Japan; University of Tokyo, Japan
Original publication
M. Leonhardt, D. Schweitzer, F. Abbass, K. K. Anjum, B. Arndt, S. Erlewein, S. Endo, P. Geissler, T. Imamura, J. I. Jäger, B. M. Latacz, P. Micke, F. Voelksen, H. Yildiz, K. Blaum, J. A. Devlin, Y. Matsuda, C. Ospelkaus, W. Quint, A. Soter, J. Walz, Y. Yamazaki, S. Ulmer, and C. Smorra.
Proton Transport from the Antimatter Factory of CERN.
Nature (2025).
DOI: https://doi.org/10.1038/s41586-025-08926-y
