反水素原子内部エネルギー差の測定精度で画期的進展 （Researchers in breakthrough precision on energy difference inside antihydrogen atoms）

2026-05-27 スウォンジー大学

＜関連情報＞

• https://www.swansea.ac.uk/press-office/news-events/news/2026/05/researchers-in-breakthrough-precision-on-energy-difference-inside-antihydrogen-atoms-.php
• https://www.nature.com/articles/s41586-026-10556-x

反水素基底状態の超微細分裂の4 ppm測定 Four ppm measurement of the antihydrogen ground-state hyperfine splitting

R. Akbari,L. O. de Araujo Azevedo,C. J. Baker,W. Bertsche,N. M. Bhatt,G. Bonomi,A. Capra,I. Carli,C. L. Cesar,M. Charlton,A. Cridland Mathad,A. Del Vincio,D. Duque Quiceno,S. Eriksson,A. Evans,J. Fajans,T. Friesen,M. C. Fujiwara,L. M. Golino,M. B. Gomes Gonçalves,J. S. Hangst,M. E. Hayden,P. Heidari,D. Hodgkinson,The ALPHA Collaboration,…
Nature  Published:27 May 2026
DOI:https://doi.org/10.1038/s41586-026-10556-x

Abstract

The hydrogen atom is a touchstone for the foundations, evolution and frontiers of quantum theory^{1,2,3,4,5,6,7,8,9}. Key spectral lines of this atom have been determined to remarkable precision^10,11. Our research focuses on the study of antihydrogen, the antimatter counterpart of hydrogen. We test fundamental symmetries of nature (such as simultaneous charge conjugation, parity inversion, and time reversal or CPT symmetry) through precision comparisons of these atomic systems¹². Recent 1S–2S spectroscopic measurements on trapped antihydrogen have achieved relative precisions of parts per trillion (refs. ^13,14). However, the ground-state hyperfine splitting, which is sensitive to the internal structure of the antiproton, has only been measured to 400 parts per million (ppm). Here we report a 4 ppm measurement of the antihydrogen ground-state hyperfine splitting energy a_1S, advancing the state-of-the-art precision¹⁵ by two orders of magnitude. From microwave spectroscopy experiments with roughly 24,000 anti-atoms, we determine \({a}_{1{\rm{S}}}/h=\mathrm{1,420,404.8}\pm 1.1(\mathrm{stat.})\pm 5.6\,(\mathrm{sys.})\,\text{kHz}\) in a 1-T magnetic field, consistent with expectations for hydrogen¹¹. At this level, our measurement is sensitive to the internal structure of the antiproton, which contributes at about 40 ppm and is approaching the limit of existing theoretical analyses¹⁶. The gains we report are the product of marked advances in magnetic trap field control, stabilization and characterization; anti-atom spin-state manipulation; and improved antihydrogen accumulation rate¹⁷.