Observation of the effect of gravity on the motion of antimatter

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 Gonçalves; 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 Ø 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

doi:10.1038/s41586-023-06527-1

Observation of the effect of gravity on the motion of antimatter

Nature. 2023 Sep;621(7980):716-722. doi: 10.1038/s41586-023-06527-1. Epub 2023 Sep 27.

Authors

E K Anderson¹, C J Baker², W Bertsche^{3

4}, N M Bhatt², G Bonomi⁵, A Capra⁶, I Carli⁶, C L Cesar⁷, M Charlton², A Christensen⁸, R Collister^{6

9}, A Cridland Mathad², D Duque Quiceno^{6

9}, S Eriksson², A Evans^{6

9}, N Evetts⁹, S Fabbri^{10

11}, J Fajans¹², A Ferwerda¹³, T Friesen¹⁴, M C Fujiwara⁶, D R Gill⁶, L M Golino², M B Gomes Gonçalves², P Grandemange⁶, P Granum¹, J S Hangst¹⁵, M E Hayden¹⁶, D Hodgkinson^{10

8}, E D Hunter⁸, C A Isaac², A J U Jimenez⁶, M A Johnson^{10

17}, J M Jones², S A Jones¹⁸, S Jonsell¹⁹, A Khramov^{6

9

20}, N Madsen², L Martin⁶, N Massacret⁶, D Maxwell², J T K McKenna^{1

10}, S Menary¹³, T Momose^{6

9

21}, M Mostamand^{6

21}, P S Mullan^{2

22}, J Nauta², K Olchanski⁶, A N Oliveira¹, J Peszka^{2

22}, A Powell¹⁴, C Ø Rasmussen²³, F Robicheaux²⁴, R L Sacramento⁷, M Sameed^{10

25}, E Sarid^{26

27}, J Schoonwater², D M Silveira⁷, J Singh¹⁰, G Smith^{6

9}, C So⁶, S Stracka²⁸, G Stutter^{1

29}, T D Tharp³⁰, K A Thompson², R I Thompson^{6

14}, E Thorpe-Woods², C Torkzaban⁸, M Urioni⁵, P Woosaree¹⁴, J S Wurtele⁸

Affiliations

¹ Department of Physics and Astronomy, Aarhus University, Aarhus, Denmark.
² Department of Physics, Faculty of Science and Engineering, Swansea University, Swansea, UK.
³ School of Physics and Astronomy, University of Manchester, Manchester, UK. william.bertsche@cern.ch.
⁴ Cockcroft Institute, Sci-Tech Daresbury, Warrington, UK. william.bertsche@cern.ch.
⁵ University of Brescia, Brescia and INFN Pavia, Pavia, Italy.
⁶ TRIUMF, Vancouver, British Columbia, Canada.
⁷ Instituto de Fisica, Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brazil.
⁸ Department of Physics, University of California at Berkeley, Berkeley, CA, USA.
⁹ Department of Physics and Astronomy, University of British Columbia, Vancouver, British Columbia, Canada.
¹⁰ School of Physics and Astronomy, University of Manchester, Manchester, UK.
¹¹ Accelerator and Technology Sector, CERN, Geneva, Switzerland.
¹² Department of Physics, University of California at Berkeley, Berkeley, CA, USA. joel@physics.berkeley.edu.
¹³ Department of Physics and Astronomy, York University, Toronto, Ontario, Canada.
¹⁴ Department of Physics and Astronomy, University of Calgary, Calgary, Alberta, Canada.
¹⁵ Department of Physics and Astronomy, Aarhus University, Aarhus, Denmark. jeffrey.hangst@cern.ch.
¹⁶ Department of Physics, Simon Fraser University, Burnaby, British Columbia, Canada.
¹⁷ Cockcroft Institute, Sci-Tech Daresbury, Warrington, UK.
¹⁸ Van Swinderen Institute for Particle Physics and Gravity, University of Groningen, Groningen, The Netherlands.
¹⁹ Department of Physics, Stockholm University, Stockholm, Sweden.
²⁰ Department of Physics, British Columbia Institute of Technology, Burnaby, British Columbia, Canada.
²¹ Department of Chemistry, University of British Columbia, Vancouver, British Columbia, Canada.
²² Institute for Particle Physics and Astrophysics, ETH, Zurich, Switzerland.
²³ Experimental Physics Department, CERN, Geneva, Switzerland.
²⁴ Department of Physics and Astronomy, Purdue University, West Lafayette, IN, USA.
²⁵ Accelerator Systems Department, CERN, Geneva, Switzerland.
²⁶ Soreq NRC, Yavne, Israel.
²⁷ Department of Physics, Ben Gurion University, Beer Sheva, Israel.
²⁸ INFN Pisa, Pisa, Italy.
²⁹ School of Mathematical and Physical Sciences, University of Sussex, Brighton, UK.
³⁰ Physics Department, Marquette University, Milwaukee, WI, USA.

Abstract

Einstein's general theory of relativity from 1915¹ remains the most successful description of gravitation. From the 1919 solar eclipse² to the observation of gravitational waves³, 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 theory⁴ appeared in 1928; the positron was observed⁵ in 1932. There has since been much speculation about gravity and antimatter. The theoretical consensus is that any laboratory mass must be attracted⁶ by the Earth, although some authors have considered the cosmological consequences if antimatter should be repelled by matter^7-10. 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.