Numerical Simulations of Hyperfine Transitions of Antihydrogen

B. Kolbinger; A. Capon; M. Diermaier; S. Lehner; C. Malbrunot; O.; Massiczek; C. Sauerzopf; M. C. Simon; E. Widmann

arXiv:1501.01420·physics.atom-ph·June 23, 2015

Numerical Simulations of Hyperfine Transitions of Antihydrogen

B. Kolbinger, A. Capon, M. Diermaier, S. Lehner, C. Malbrunot, O., Massiczek, C. Sauerzopf, M. C. Simon, E. Widmann

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TL;DR

This paper presents numerical simulations of antihydrogen hyperfine transitions to estimate the event requirements and precision for CPT symmetry tests in antimatter physics.

Contribution

It introduces detailed simulations of antihydrogen hyperfine transitions, aiding in planning high-precision CPT symmetry experiments.

Findings

01

Simulations estimate the number of antihydrogen events needed.

02

Results indicate achievable measurement precision.

03

Provides guidance for experimental design in antimatter spectroscopy.

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.

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