| Article | |
| Report number | arXiv:1501.01420 |
| Title | Numerical Simulations of Hyperfine Transitions of Antihydrogen |
| Author(s) | Kolbinger, B. (Stefan Meyer Inst. Subatomare Phys.) ; Capon, A. (Stefan Meyer Inst. Subatomare Phys.) ; Diermaier, M. (Stefan Meyer Inst. Subatomare Phys.) ; Lehner, S. (Stefan Meyer Inst. Subatomare Phys.) ; Malbrunot, C. (CERN ; Stefan Meyer Inst. Subatomare Phys.) ; Massiczek, O. (Stefan Meyer Inst. Subatomare Phys.) ; Sauerzopf, C. (Stefan Meyer Inst. Subatomare Phys.) ; Simon, M.C. (Stefan Meyer Inst. Subatomare Phys. ; CERN) ; Widmann, E. (Stefan Meyer Inst. Subatomare Phys.) |
| Publication | 2015-02-04 |
| Imprint | 07 Jan 2015 |
| Number of pages | 5 |
| In: | Hyperfine Interact. 233 (2015) 47-51 |
| In: | 5th International Conference on Exotic Atoms and Related Topics, Vienna, Austria, 15 - 19 Sep 2014, pp.47-51 |
| DOI | 10.1007/s10751-015-1130-3 |
| Subject category | Other Fields of Physics |
| Accelerator/Facility, Experiment | CERN AD ; ASACUSA AD-3 |
| Abstract | One of the ASACUSA (Atomic Spectroscopy And Collisions Using Slow Antiprotons) collaboration's goals is the measurement of the ground state hyperfine transition frequency in antihydrogen, the antimatter counterpart of one of the best known systems in physics. This high precision experiment yields a sensitive test of the fundamental symmetry of CPT. Numerical simulations of hyperfine transitions of antihydrogen atoms have been performed providing information on the required antihydrogen events and the achievable precision. |
| Copyright/License | arXiv nonexclusive-distrib. 1.0 |
Corresponding record in: Inspire
Record created 2015-01-09, last modified 2023-03-14
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