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Published February 24, 2021 | Supplemental Material
Journal Article Open

The asymmetry of antimatter in the proton

Dove, J.
Kerns, B.
McClellan, R. E.
Miyasaka, S.
Morton, D. H.
Nagai, K.
Prasad, S.
Sanftl, F.
Scott, M. B. C.
Tadepalli, A. S.
Aidala, C. A.
Arrington, J.
Ayuso, C.
Barker, C. L.
Brown, C. N.
Chang, W. C.
Chen, A.
Christian, D. C.
Dannowitz, B. P.
Daugherity, M. ORCID icon
Diefenthaler, M. ORCID icon
El Fassi, L.
Geesaman, D. F.
Gilman, R.
Goto, Y. ORCID icon
Guo, L.
Guo, R.
Hague, T. J.
Holt, R. J.
Isenhower, D.
Kinney, E. R. ORCID icon
Kitts, N.
Klein, A.
Kleinjan, D. W.
Kudo, Y.
Leung, C. ORCID icon
Lin, P.-J.
Liu, K. ORCID icon
Liu, M. X.
Lorenzon, W.
Makins, N. C. R.
Mesquita de Medeiros, M.
McGaughey, P. L.
Miyachi, Y.
Mooney, I.
Nakahara, K.
Nakano, K.
Nara, S.
Peng, J.-C.
Puckett, A. J.
Ramson, B. J.
Reimer, P. E. ORCID icon
Rubin, J. G. ORCID icon
Sawada, S. ORCID icon
Sawada, T. ORCID icon
Shibata, T.-A.
Su, D. ORCID icon
Teo, M.
Tice, B. G.
Towell, R. S. ORCID icon
Uemura, S. ORCID icon
Watson, S.
Wang, S. G. ORCID icon
Wickes, A. B.
Wu, J.
Xi, Z.
Ye, Z. ORCID icon

Abstract

The fundamental building blocks of the proton—quarks and gluons—have been known for decades. However, we still have an incomplete theoretical and experimental understanding of how these particles and their dynamics give rise to the quantum bound state of the proton and its physical properties, such as its spin. The two up quarks and the single down quark that comprise the proton in the simplest picture account only for a few per cent of the proton mass, the bulk of which is in the form of quark kinetic and potential energy and gluon energy from the strong force. An essential feature of this force, as described by quantum chromodynamics, is its ability to create matter–antimatter quark pairs inside the proton that exist only for a very short time. Their fleeting existence makes the antimatter quarks within protons difficult to study, but their existence is discernible in reactions in which a matter–antimatter quark pair annihilates. In this picture of quark–antiquark creation by the strong force, the probability distributions as a function of momentum for the presence of up and down antimatter quarks should be nearly identical, given that their masses are very similar and small compared to the mass of the proton. Here we provide evidence from muon pair production measurements that these distributions are considerably different, with more abundant down antimatter quarks than up antimatter quarks over a wide range of momenta. These results are expected to revive interest in several proposed mechanisms for the origin of this antimatter asymmetry in the proton that had been disfavoured by previous results, and point to future measurements that can distinguish between these mechanisms.

Additional Information

© 2021 Nature Publishing Group. Received 02 June 2020; Accepted 15 December 2020; Published 24 February 2021. We thank G. T. Garvey for contributions to the early stages of this experiment. We also thank the Fermilab Accelerator Division and Particle Physics Division for their support of this experiment. This work was performed by the SeaQuest Collaboration, whose work was supported in part by the US Department of Energy under grants DE-AC02-06CH11357, DE-FG02-07ER41528, DE-SC0006963; the US National Science Foundation under grants PHY 0969239, PHY 1306126, PHY 1452636, PHY 1505458, PHY 1614456; the DP&A and ORED at Mississippi State University; the JSPS (Japan) KAKENHI through grant numbers 21244028, 25247037, 25800133; the Tokyo Tech Global COE Program, Japan; the Yamada Science Foundation of Japan; and the Ministry of Science and Technology (MOST), Taiwan. Fermilab is operated by Fermi Research Alliance, LLC, under contract number DE-AC02-07CH11359 with the US Department of Energy. Data availability: Raw data were generated at the Fermi National Accelerator Laboratory. Derived data supporting the findings of this study are available from the corresponding author upon request. Author Contributions: P.E.R. and D.F.G. are the co-spokespersons for the experiment. The entire SeaQuest Collaboration constructed the experiment and participated in the data collection and analysis. Substantial contributions to the cross-section ratio analysis were made by graduate students J.D., B.K., R.E.M., S.M., D.H.M., K. Nagai, S.P., F.S., M.B.C.S. and A.S.T. The development of the technique of extrapolation to zero intensity greatly benefited from the work of A.S.T. All authors reviewed the manuscript. The authors declare no competing interests. Peer review information: Nature thanks Gerald Miller, Gunar Schnell and the other, anonymous, reviewer(s) for their contribution to the peer review of this work.

Errata

Dove, J., Kerns, B., McClellan, R.E. et al. Publisher Correction: The asymmetry of antimatter in the proton. Nature (2022). https://doi.org/10.1038/s41586-022-04707-z

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Additional details

Identifiers Related works Funding Dates
Created:
August 22, 2023
Modified:
October 23, 2023