Literature DB >> 28770838

Observation of the hyperfine spectrum of antihydrogen.

M Ahmadi1, B X R Alves2, C J Baker3, W Bertsche4,5, E Butler6, A Capra7, C Carruth8, C L Cesar9, M Charlton3, S Cohen10, R Collister7, S Eriksson3, A Evans11, N Evetts12, J Fajans8, T Friesen2, M C Fujiwara7, D R Gill7, A Gutierrez12,13, J S Hangst2, W N Hardy12, M E Hayden14, C A Isaac3, A Ishida15, M A Johnson4,5, S A Jones3, S Jonsell16, L Kurchaninov7, N Madsen3, M Mathers17, D Maxwell3, J T K McKenna7, S Menary17, J M Michan7,18, T Momose12, J J Munich14, P Nolan1, K Olchanski7, A Olin7,19, P Pusa1, C Ø Rasmussen2, F Robicheaux20, R L Sacramento9, M Sameed3, E Sarid21, D M Silveira9, S Stracka7,22, G Stutter2, C So11, T D Tharp23, J E Thompson17, R I Thompson11, D P van der Werf3,24, J S Wurtele8.   

Abstract

The observation of hyperfine structure in atomic hydrogen by Rabi and co-workers and the measurement of the zero-field ground-state splitting at the level of seven parts in 1013 are important achievements of mid-twentieth-century physics. The work that led to these achievements also provided the first evidence for the anomalous magnetic moment of the electron, inspired Schwinger's relativistic theory of quantum electrodynamics and gave rise to the hydrogen maser, which is a critical component of modern navigation, geo-positioning and very-long-baseline interferometry systems. Research at the Antiproton Decelerator at CERN by the ALPHA collaboration extends these enquiries into the antimatter sector. Recently, tools have been developed that enable studies of the hyperfine structure of antihydrogen-the antimatter counterpart of hydrogen. The goal of such studies is to search for any differences that might exist between this archetypal pair of atoms, and thereby to test the fundamental principles on which quantum field theory is constructed. Magnetic trapping of antihydrogen atoms provides a means of studying them by combining electromagnetic interaction with detection techniques that are unique to antimatter. Here we report the results of a microwave spectroscopy experiment in which we probe the response of antihydrogen over a controlled range of frequencies. The data reveal clear and distinct signatures of two allowed transitions, from which we obtain a direct, magnetic-field-independent measurement of the hyperfine splitting. From a set of trials involving 194 detected atoms, we determine a splitting of 1,420.4 ± 0.5 megahertz, consistent with expectations for atomic hydrogen at the level of four parts in 104. This observation of the detailed behaviour of a quantum transition in an atom of antihydrogen exemplifies tests of fundamental symmetries such as charge-parity-time in antimatter, and the techniques developed here will enable more-precise such tests.

Entities:  

Year:  2017        PMID: 28770838     DOI: 10.1038/nature23446

Source DB:  PubMed          Journal:  Nature        ISSN: 0028-0836            Impact factor:   49.962


  6 in total

1.  Production and detection of cold antihydrogen atoms.

Authors:  M Amoretti; C Amsler; G Bonomi; A Bouchta; P Bowe; C Carraro; C L Cesar; M Charlton; M J T Collier; M Doser; V Filippini; K S Fine; A Fontana; M C Fujiwara; R Funakoshi; P Genova; J S Hangst; R S Hayano; M H Holzscheiter; L V Jørgensen; V Lagomarsino; R Landua; D Lindelöf; E Lodi Rizzini; M Macrì; N Madsen; G Manuzio; M Marchesotti; P Montagna; H Pruys; C Regenfus; P Riedler; J Rochet; A Rotondi; G Rouleau; G Testera; A Variola; T L Watson; D P van der Werf
Journal:  Nature       Date:  2002-09-18       Impact factor: 49.962

2.  Resonant quantum transitions in trapped antihydrogen atoms.

Authors:  C Amole; M D Ashkezari; M Baquero-Ruiz; W Bertsche; P D Bowe; E Butler; A Capra; C L Cesar; M Charlton; A Deller; P H Donnan; S Eriksson; J Fajans; T Friesen; M C Fujiwara; D R Gill; A Gutierrez; J S Hangst; W N Hardy; M E Hayden; A J Humphries; C A Isaac; S Jonsell; L Kurchaninov; A Little; N Madsen; J T K McKenna; S Menary; S C Napoli; P Nolan; K Olchanski; A Olin; P Pusa; C Ø Rasmussen; F Robicheaux; E Sarid; C R Shields; D M Silveira; S Stracka; C So; R I Thompson; D P van der Werf; J S Wurtele
Journal:  Nature       Date:  2012-03-07       Impact factor: 49.962

3.  Trapped antihydrogen.

Authors:  G B Andresen; M D Ashkezari; M Baquero-Ruiz; W Bertsche; P D Bowe; E Butler; C L Cesar; S Chapman; M Charlton; A Deller; S Eriksson; J Fajans; T Friesen; M C Fujiwara; D R Gill; A Gutierrez; J S Hangst; W N Hardy; M E Hayden; A J Humphries; R Hydomako; M J Jenkins; S Jonsell; L V Jørgensen; L Kurchaninov; N Madsen; S Menary; P Nolan; K Olchanski; A Olin; A Povilus; P Pusa; F Robicheaux; E Sarid; S Seif el Nasr; D M Silveira; C So; J W Storey; R I Thompson; D P van der Werf; J S Wurtele; Y Yamazaki
Journal:  Nature       Date:  2010-11-17       Impact factor: 49.962

4.  Positron trapping in an electrostatic well by inelastic collisions with nitrogen molecules.

Authors: 
Journal:  Phys Rev A       Date:  1992-11-01       Impact factor: 3.140

5.  Observation of the 1S-2S transition in trapped antihydrogen.

Authors:  M Ahmadi; B X R Alves; C J Baker; W Bertsche; E Butler; A Capra; C Carruth; C L Cesar; M Charlton; S Cohen; R Collister; S Eriksson; A Evans; N Evetts; J Fajans; T Friesen; M C Fujiwara; D R Gill; A Gutierrez; J S Hangst; W N Hardy; M E Hayden; C A Isaac; A Ishida; M A Johnson; S A Jones; S Jonsell; L Kurchaninov; N Madsen; M Mathers; D Maxwell; J T K McKenna; S Menary; J M Michan; T Momose; J J Munich; P Nolan; K Olchanski; A Olin; P Pusa; C Ø Rasmussen; F Robicheaux; R L Sacramento; M Sameed; E Sarid; D M Silveira; S Stracka; G Stutter; C So; T D Tharp; J E Thompson; R I Thompson; D P van der Werf; J S Wurtele
Journal:  Nature       Date:  2016-12-19       Impact factor: 49.962

6.  A source of antihydrogen for in-flight hyperfine spectroscopy.

Authors:  N Kuroda; S Ulmer; D J Murtagh; S Van Gorp; Y Nagata; M Diermaier; S Federmann; M Leali; C Malbrunot; V Mascagna; O Massiczek; K Michishio; T Mizutani; A Mohri; H Nagahama; M Ohtsuka; B Radics; S Sakurai; C Sauerzopf; K Suzuki; M Tajima; H A Torii; L Venturelli; B Wünschek; J Zmeskal; N Zurlo; H Higaki; Y Kanai; E Lodi Rizzini; Y Nagashima; Y Matsuda; E Widmann; Y Yamazaki
Journal:  Nat Commun       Date:  2014       Impact factor: 14.919
  6 in total
  11 in total

1.  Estimation of antihydrogen properties in experiments with small signal deficit.

Authors:  B Radics
Journal:  Proc Math Phys Eng Sci       Date:  2019-03-13       Impact factor: 2.704

2.  The race to reveal antimatter's secrets.

Authors:  Elizabeth Gibney
Journal:  Nature       Date:  2017-08-02       Impact factor: 49.962

Review 3.  Prospects for testing Lorentz and CPT symmetry with antiprotons.

Authors:  Arnaldo J Vargas
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2018-03-28       Impact factor: 4.226

Review 4.  Recent progress of laser spectroscopy experiments on antiprotonic helium.

Authors:  Masaki Hori
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2018-03-28       Impact factor: 4.226

5.  Erratum: Observation of the hyperfine spectrum of antihydrogen.

Authors:  M Ahmadi; B X R Alves; C J Baker; W Bertsche; E Butler; A Capra; C Carruth; C L Cesar; M Charlton; S Cohen; R Collister; S Eriksson; A Evans; N Evetts; J Fajans; T Friesen; M C Fujiwara; D R Gill; A Gutierrez; J S Hangst; W N Hardy; M E Hayden; C A Isaac; A Ishida; M A Johnson; S A Jones; S Jonsell; L Kurchaninov; N Madsen; M Mathers; D Maxwell; J T K McKenna; S Menary; J M Michan; T Momose; J J Munich; P Nolan; K Olchanski; A Olin; P Pusa; C Ø Rasmussen; F Robicheaux; R L Sacramento; M Sameed; E Sarid; D M Silveira; S Stracka; G Stutter; C So; T D Tharp; J E Thompson; R I Thompson; D P van der Werf; J S Wurtele
Journal:  Nature       Date:  2017-12-20       Impact factor: 49.962

6.  Precision measurements on trapped antihydrogen in the ALPHA experiment.

Authors:  S Eriksson
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2018-03-28       Impact factor: 4.226

Review 7.  Prospects for comparison of matter and antimatter gravitation with ALPHA-g.

Authors:  W A Bertsche
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2018-03-28       Impact factor: 4.226

8.  The ASACUSA antihydrogen and hydrogen program: results and prospects.

Authors:  C Malbrunot; C Amsler; S Arguedas Cuendis; H Breuker; P Dupre; M Fleck; H Higaki; Y Kanai; B Kolbinger; N Kuroda; M Leali; V Mäckel; V Mascagna; O Massiczek; Y Matsuda; Y Nagata; M C Simon; H Spitzer; M Tajima; S Ulmer; L Venturelli; E Widmann; M Wiesinger; Y Yamazaki; J Zmeskal
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2018-03-28       Impact factor: 4.226

Review 9.  Challenging the standard model by high-precision comparisons of the fundamental properties of protons and antiprotons.

Authors:  S Ulmer; A Mooser; H Nagahama; S Sellner; C Smorra
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2018-03-28       Impact factor: 4.226

10.  Characterization of the 1S-2S transition in antihydrogen.

Authors:  M Ahmadi; B X R Alves; C J Baker; W Bertsche; A Capra; C Carruth; C L Cesar; M Charlton; S Cohen; R Collister; S Eriksson; A Evans; N Evetts; J Fajans; T Friesen; M C Fujiwara; D R Gill; J S Hangst; W N Hardy; M E Hayden; C A Isaac; M A Johnson; J M Jones; S A Jones; S Jonsell; A Khramov; P Knapp; L Kurchaninov; N Madsen; D Maxwell; J T K McKenna; S Menary; T Momose; J J Munich; K Olchanski; A Olin; P Pusa; C Ø Rasmussen; F Robicheaux; R L Sacramento; M Sameed; E Sarid; D M Silveira; G Stutter; C So; T D Tharp; R I Thompson; D P van der Werf; J S Wurtele
Journal:  Nature       Date:  2018-04-04       Impact factor: 49.962
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