Proton transport from the antimatter factory of CERN

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autorschaft

  • M. Leonhardt
  • D. Schweitzer
  • F. Abbass
  • K. K. Anjum
  • B. Arndt
  • S. Erlewein
  • S. Endoh
  • 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
  • C. Smorra

Organisationseinheiten

Externe Organisationen

  • Universitätsklinikum Düsseldorf
  • Ulmer Fundamental Symmetries Laboratory
  • Johannes Gutenberg-Universität Mainz
  • GSI Helmholtzzentrum für Schwerionenforschung GmbH
  • Max-Planck-Institut für Kernphysik
  • CERN - Europäische Organisation für Kernforschung
  • University of Tokyo (UTokyo)
  • Physikalisch-Technische Bundesanstalt (PTB)
  • Friedrich-Schiller-Universität Jena
  • Imperial College London
  • ETH Zürich
  • Helmholtz-Institut Mainz
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)871-875
Seitenumfang5
FachzeitschriftNATURE
Jahrgang641
PublikationsstatusVeröffentlicht - 14 Mai 2025

Abstract

Precision measurements using low-energy antiprotons, exclusively available at the antimatter factory (AMF) of CERN1, offer stringent tests of charge–parity–time (CPT) invariance, which is a fundamental symmetry in the Standard Model of particle physics2. These tests have been realized, for example, in antiprotonic helium3 and antihydrogen4. In our cryogenic Penning-trap experiments5, we measure the magnetic moments6,7 and charge-to-mass ratios of protons and antiprotons and now provide the most precise test of CPT invariance in the baryon sector8. Our experiments are limited by magnetic field fluctuations imposed by the decelerators in the AMF; therefore, we are advancing the relocation of antiprotons to dedicated precision laboratories. Here we present the successful transport of a trapped proton cloud from the AMF using BASE-STEP9—a transportable, superconducting, autonomous and open Penning-trap system that can distribute antiprotons into other experiments. We transferred the trapped protons from our experimental area at the AMF onto a truck and transported them across the Meyrin site of CERN, demonstrating autonomous operation without external power for 4 h and loss-free proton relocation. We thereby confirm the feasibility of transferring particles into low-noise laboratories in the vicinity of the AMF and of using a power generator on the truck10 to reach laboratories throughout Europe. This marks the potential start of a new era in precision antimatter research, enabling low-noise measurements of antiprotons, the charged antimatter ions H¯+11 and H¯2− (ref. 12), and other accelerator-produced ions, such as hydrogen-like lead or uranium ions13,14.

ASJC Scopus Sachgebiete

Zitieren

Proton transport from the antimatter factory of CERN. / Leonhardt, M.; Schweitzer, D.; Abbass, F. et al.
in: NATURE, Jahrgang 641, 14.05.2025, S. 871-875.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Leonhardt, M, Schweitzer, D, Abbass, F, Anjum, KK, Arndt, B, Erlewein, S, Endoh, S, Geissler, P, Imamura, T, Jäger, JI, Latacz, BM, Micke, P, Voelksen, F, Yildiz, H, Blaum, K, Devlin, JA, Matsuda, Y, Ospelkaus, C, Quint, W, Soter, A, Walz, J, Yamazaki, Y, Ulmer, S & Smorra, C 2025, 'Proton transport from the antimatter factory of CERN', NATURE, Jg. 641, S. 871-875. https://doi.org/10.1038/s41586-025-08926-y
Leonhardt, M., Schweitzer, D., Abbass, F., Anjum, K. K., Arndt, B., Erlewein, S., Endoh, S., Geissler, P., Imamura, T., Jäger, J. I., Latacz, B. M., Micke, P., Voelksen, F., Yildiz, H., Blaum, K., Devlin, J. A., Matsuda, Y., Ospelkaus, C., Quint, W., ... Smorra, C. (2025). Proton transport from the antimatter factory of CERN. NATURE, 641, 871-875. https://doi.org/10.1038/s41586-025-08926-y
Leonhardt M, Schweitzer D, Abbass F, Anjum KK, Arndt B, Erlewein S et al. Proton transport from the antimatter factory of CERN. NATURE. 2025 Mai 14;641:871-875. doi: 10.1038/s41586-025-08926-y
Leonhardt, M. ; Schweitzer, D. ; Abbass, F. et al. / Proton transport from the antimatter factory of CERN. in: NATURE. 2025 ; Jahrgang 641. S. 871-875.
Download
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abstract = "Precision measurements using low-energy antiprotons, exclusively available at the antimatter factory (AMF) of CERN1, offer stringent tests of charge–parity–time (CPT) invariance, which is a fundamental symmetry in the Standard Model of particle physics2. These tests have been realized, for example, in antiprotonic helium3 and antihydrogen4. In our cryogenic Penning-trap experiments5, we measure the magnetic moments6,7 and charge-to-mass ratios of protons and antiprotons and now provide the most precise test of CPT invariance in the baryon sector8. Our experiments are limited by magnetic field fluctuations imposed by the decelerators in the AMF; therefore, we are advancing the relocation of antiprotons to dedicated precision laboratories. Here we present the successful transport of a trapped proton cloud from the AMF using BASE-STEP9—a transportable, superconducting, autonomous and open Penning-trap system that can distribute antiprotons into other experiments. We transferred the trapped protons from our experimental area at the AMF onto a truck and transported them across the Meyrin site of CERN, demonstrating autonomous operation without external power for 4 h and loss-free proton relocation. We thereby confirm the feasibility of transferring particles into low-noise laboratories in the vicinity of the AMF and of using a power generator on the truck10 to reach laboratories throughout Europe. This marks the potential start of a new era in precision antimatter research, enabling low-noise measurements of antiprotons, the charged antimatter ions H¯+11 and H¯2− (ref. 12), and other accelerator-produced ions, such as hydrogen-like lead or uranium ions13,14.",
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T1 - Proton transport from the antimatter factory of CERN

AU - Leonhardt, M.

AU - Schweitzer, D.

AU - Abbass, F.

AU - Anjum, K. K.

AU - Arndt, B.

AU - Erlewein, S.

AU - Endoh, S.

AU - Geissler, P.

AU - Imamura, T.

AU - Jäger, J. I.

AU - Latacz, B. M.

AU - Micke, P.

AU - Voelksen, F.

AU - Yildiz, H.

AU - Blaum, K.

AU - Devlin, J. A.

AU - Matsuda, Y.

AU - Ospelkaus, C.

AU - Quint, W.

AU - Soter, A.

AU - Walz, J.

AU - Yamazaki, Y.

AU - Ulmer, S.

AU - Smorra, C.

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/5/14

Y1 - 2025/5/14

N2 - Precision measurements using low-energy antiprotons, exclusively available at the antimatter factory (AMF) of CERN1, offer stringent tests of charge–parity–time (CPT) invariance, which is a fundamental symmetry in the Standard Model of particle physics2. These tests have been realized, for example, in antiprotonic helium3 and antihydrogen4. In our cryogenic Penning-trap experiments5, we measure the magnetic moments6,7 and charge-to-mass ratios of protons and antiprotons and now provide the most precise test of CPT invariance in the baryon sector8. Our experiments are limited by magnetic field fluctuations imposed by the decelerators in the AMF; therefore, we are advancing the relocation of antiprotons to dedicated precision laboratories. Here we present the successful transport of a trapped proton cloud from the AMF using BASE-STEP9—a transportable, superconducting, autonomous and open Penning-trap system that can distribute antiprotons into other experiments. We transferred the trapped protons from our experimental area at the AMF onto a truck and transported them across the Meyrin site of CERN, demonstrating autonomous operation without external power for 4 h and loss-free proton relocation. We thereby confirm the feasibility of transferring particles into low-noise laboratories in the vicinity of the AMF and of using a power generator on the truck10 to reach laboratories throughout Europe. This marks the potential start of a new era in precision antimatter research, enabling low-noise measurements of antiprotons, the charged antimatter ions H¯+11 and H¯2− (ref. 12), and other accelerator-produced ions, such as hydrogen-like lead or uranium ions13,14.

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