Observation of the Effect of Gravity on the Motion of Antimatter

Overview

Journal Nature

Specialty Science

Date 2023 Sep 27

PMID 37758891

Authors

E K Anderson

C J Baker

W Bertsche

N M Bhatt

G Bonomi

A Capra

I Carli

C L Cesar

M Charlton

A Christensen

R Collister

A Cridland Mathad

D Duque Quiceno

S Eriksson

A Evans

N Evetts

S Fabbri

J Fajans

A Ferwerda

T Friesen

M C Fujiwara

D R Gill

L M Golino

M B Gomes Goncalves

P Grandemange

P Granum

J S Hangst

M E Hayden

D Hodgkinson

E D Hunter

C A Isaac

A J U Jimenez

M A Johnson

J M Jones

S A Jones

S Jonsell

A Khramov

N Madsen

L Martin

N Massacret

D Maxwell

J T K McKenna

S Menary

T Momose

M Mostamand

P S Mullan

J Nauta

K Olchanski

A N Oliveira

J Peszka

A Powell

C O Rasmussen

F Robicheaux

R L Sacramento

M Sameed

E Sarid

J Schoonwater

D M Silveira

J Singh

G Smith

C So

S Stracka

G Stutter

T D Tharp

K A Thompson

R I Thompson

E Thorpe-Woods

C Torkzaban

M Urioni

P Woosaree

J S Wurtele

Affiliations

Soon will be listed here.

Abstract

Einstein's general theory of relativity from 1915 remains the most successful description of gravitation. From the 1919 solar eclipse to the observation of gravitational waves, the theory has passed many crucial experimental tests. However, the evolving concepts of dark matter and dark energy illustrate that there is much to be learned about the gravitating content of the universe. Singularities in the general theory of relativity and the lack of a quantum theory of gravity suggest that our picture is incomplete. It is thus prudent to explore gravity in exotic physical systems. Antimatter was unknown to Einstein in 1915. Dirac's theory appeared in 1928; the positron was observed in 1932. There has since been much speculation about gravity and antimatter. The theoretical consensus is that any laboratory mass must be attracted by the Earth, although some authors have considered the cosmological consequences if antimatter should be repelled by matter. In the general theory of relativity, the weak equivalence principle (WEP) requires that all masses react identically to gravity, independent of their internal structure. Here we show that antihydrogen atoms, released from magnetic confinement in the ALPHA-g apparatus, behave in a way consistent with gravitational attraction to the Earth. Repulsive 'antigravity' is ruled out in this case. This experiment paves the way for precision studies of the magnitude of the gravitational acceleration between anti-atoms and the Earth to test the WEP.

Citing Articles

Production and study of antideuterium with the GBAR beamline.

Blumer P, Ohayon B, Crivelli P Eur Phys J D At Mol Opt Phys. 2025; 79(3):17.

PMID: 40046814 PMC: 11876288. DOI: 10.1140/epjd/s10053-025-00963-6.

Design of a microwave spectrometer for high-precision Lamb shift spectroscopy of antihydrogen atoms.

Tanaka T, Blumer P, Janka G, Ohayon B, Regenfus C, Asari M Interactions (Cham). 2024; 245(1):30.

PMID: 39619620 PMC: 11604687. DOI: 10.1007/s10751-024-01876-3.

GRASIAN: shaping and characterization of the cold hydrogen and deuterium beams for the forthcoming first demonstration of gravitational quantum states of atoms.

Killian C, Blumer P, Crivelli P, Hanski O, Kloppenburg D, Nez F Eur Phys J D At Mol Opt Phys. 2024; 78(10):132.

PMID: 39483954 PMC: 11522151. DOI: 10.1140/epjd/s10053-024-00916-5.

Cooling positronium to ultralow velocities with a chirped laser pulse train.

Shu K, Tajima Y, Uozumi R, Miyamoto N, Shiraishi S, Kobayashi T Nature. 2024; 633(8031):793-797.

PMID: 39261730 PMC: 11424484. DOI: 10.1038/s41586-024-07912-0.

Antimatter falls down, not up: CERN experiment confirms theory.

Castelvecchi D Nature. 2023; 622(7981):14-15.

PMID: 37759123 DOI: 10.1038/d41586-023-03043-0.

References

Abbott B, Abbott R, Abbott T, Abernathy M, Acernese F, Ackley K . Observation of Gravitational Waves from a Binary Black Hole Merger. Phys Rev Lett. 2016; 116(6):061102. DOI: 10.1103/PhysRevLett.116.061102. View

Touboul P, Metris G, Rodrigues M, Berge J, Robert A, Baghi Q . MICROSCOPE Mission: Final Results of the Test of the Equivalence Principle. Phys Rev Lett. 2022; 129(12):121102. DOI: 10.1103/PhysRevLett.129.121102. View

Andresen G, Ashkezari M, Baquero-Ruiz M, Bertsche W, Bowe P, Butler E . Evaporative cooling of antiprotons to cryogenic temperatures. Phys Rev Lett. 2010; 105(1):013003. DOI: 10.1103/PhysRevLett.105.013003. View

Borchert M, Devlin J, Erlewein S, Fleck M, Harrington J, Higuchi T . A 16-parts-per-trillion measurement of the antiproton-to-proton charge-mass ratio. Nature. 2022; 601(7891):53-57. DOI: 10.1038/s41586-021-04203-w. View

HUGHES , Holzscheiter . Constraints on the gravitational properties of antiprotons and positrons from cyclotron-frequency measurements. Phys Rev Lett. 1991; 66(7):854-857. DOI: 10.1103/PhysRevLett.66.854. View

Amoretti M, Amsler C, Bonomi G, Bouchta A, Bowe P, Carraro C . Production and detection of cold antihydrogen atoms. Nature. 2002; 419(6906):456-9. DOI: 10.1038/nature01096. View

Andresen G, Ashkezari M, Baquero-Ruiz M, Bertsche W, Bowe P, Butler E . Trapped antihydrogen. Nature. 2010; 468(7324):673-6. DOI: 10.1038/nature09610. View

Charman A, Amole C, Ashkezari M, Baquero-Ruiz M, Bertsche W, Butler E . Description and first application of a new technique to measure the gravitational mass of antihydrogen. Nat Commun. 2013; 4:1785. PMC: 3644108. DOI: 10.1038/ncomms2787. View

Ahmadi M, Alves B, Baker C, Bertsche W, Butler E, Capra A . Antihydrogen accumulation for fundamental symmetry tests. Nat Commun. 2017; 8(1):681. PMC: 5613003. DOI: 10.1038/s41467-017-00760-9. View

10.

Baker C, Bertsche W, Capra A, Carruth C, Cesar C, Charlton M . Laser cooling of antihydrogen atoms. Nature. 2021; 592(7852):35-42. PMC: 8012212. DOI: 10.1038/s41586-021-03289-6. View

11.

Amole C, Ashkezari M, Baquero-Ruiz M, Bertsche W, Bowe P, Butler E . Resonant quantum transitions in trapped antihydrogen atoms. Nature. 2012; 483(7390):439-43. DOI: 10.1038/nature10942. View

12.

Ahmadi M, Alves B, Baker C, Bertsche W, Butler E, Capra A . Observation of the hyperfine spectrum of antihydrogen. Nature. 2017; 548(7665):66-69. DOI: 10.1038/nature23446. View

13.

Ahmadi M, Alves B, Baker C, Bertsche W, Butler E, Capra A . Observation of the 1S-2S transition in trapped antihydrogen. Nature. 2016; 541(7638):506-510. DOI: 10.1038/nature21040. View

14.

Ahmadi M, Alves B, Baker C, Bertsche W, Capra A, Carruth C . Characterization of the 1S-2S transition in antihydrogen. Nature. 2018; 557(7703):71-75. PMC: 6784861. DOI: 10.1038/s41586-018-0017-2. View

15.

Ahmadi M, Alves B, Baker C, Bertsche W, Capra A, Carruth C . Observation of the 1S-2P Lyman-α transition in antihydrogen. Nature. 2018; 561(7722):211-215. PMC: 6786973. DOI: 10.1038/s41586-018-0435-1. View

16.

Ahmadi M, Alves B, Baker C, Bertsche W, Capra A, Carruth C . Enhanced Control and Reproducibility of Non-Neutral Plasmas. Phys Rev Lett. 2018; 120(2):025001. DOI: 10.1103/PhysRevLett.120.025001. View

17.

Ahmadi M, Baquero-Ruiz M, Bertsche W, Butler E, Capra A, Carruth C . An improved limit on the charge of antihydrogen from stochastic acceleration. Nature. 2016; 529(7586):373-6. DOI: 10.1038/nature16491. View

18.

Baker C, Bertsche W, Capra A, Cesar C, Charlton M, Cridland Mathad A . Sympathetic cooling of positrons to cryogenic temperatures for antihydrogen production. Nat Commun. 2021; 12(1):6139. PMC: 8536749. DOI: 10.1038/s41467-021-26086-1. View

19.

Hamilton P, Zhmoginov A, Robicheaux F, Fajans J, Wurtele J, Muller H . Antimatter interferometry for gravity measurements. Phys Rev Lett. 2014; 112(12):121102. DOI: 10.1103/PhysRevLett.112.121102. View

20.

Hunter E, Fajans J, Lewis N, Povilus A, Sierra C, So C . Plasma temperature measurement with a silicon photomultiplier (SiPM). Rev Sci Instrum. 2020; 91(10):103502. DOI: 10.1063/5.0006672. View