Physics:Proton radius puzzle

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Short description: Unanswered problem in physics

The proton radius puzzle is an unanswered problem in physics relating to the size of the proton.[1] Historically the proton charge radius was measured by two independent methods, which converged to a value of about 0.877 femtometres (1 fm = 10−15 m). This value was challenged by a 2010 experiment using a third method, which produced a radius about 4% smaller than this, at 0.842 femtometres.[2] New experimental results reported in the autumn of 2019 agree with the smaller measurement, as does a re-analysis of older data published in 2022. While some believe that this difference has been resolved,[3][4] this opinion is not yet universally held.[5][6]

Problem

Prior to 2010, the proton charge radius was measured using one of two methods: one relying on spectroscopy, and one relying on nuclear scattering.[7]

Spectroscopy method

The spectroscopy method uses the energy levels of electrons orbiting the nucleus. The exact values of the energy levels are sensitive to the distribution of charge in the nucleus. For hydrogen, whose nucleus consists only of one proton, this indirectly measures the proton charge radius. Measurements of hydrogen's energy levels are now so precise that the accuracy of the proton radius is the limiting factor when comparing experimental results to theoretical calculations. This method produces a proton radius of about 0.8768(69) fm, with approximately 1% relative uncertainty.[2]

Nuclear scattering

The nuclear method is similar to Rutherford's scattering experiments that established the existence of the nucleus. Small particles such as electrons can be fired at a proton, and by measuring how the electrons are scattered, the size of the proton can be inferred. Consistent with the spectroscopy method, this produces a proton radius of about 0.8775(5) fm.[8]

2010 experiment

In 2010, Pohl et al. published the results of an experiment relying on muonic hydrogen as opposed to normal hydrogen. Conceptually, this is similar to the spectroscopy method. However, the much higher mass of a muon causes it to orbit 207 times closer than an electron to the hydrogen nucleus, where it is consequently much more sensitive to the size of the proton. The resulting radius was recorded as 0.842(1) fm, 5 standard deviations (5σ) smaller than the prior measurements.[2][9] The newly measured radius is 4% smaller than the prior measurements, which were believed to be accurate within 1%. (The new measurement's uncertainty limit of only 0.1% makes a negligible contribution to the discrepancy.)[10]

Since 2010, additional measurements using electrons with the previous methods have slightly reduced the estimated radius to 0.8751(61) fm,[11] but by reducing the uncertainty even more the disagreement with the muonic hydrogen experiment has worsened to over 7σ.

A follow-up experiment by Pohl et al. in August 2016 used a deuterium atom to create muonic deuterium and measured the deuteron radius. This experiment allowed the measurements to be 2.7 times more accurate, but also found a discrepancy of 7.5 standard deviations smaller than the expected value.[12][13] In 2017 a group at the Max-Planck-Institute of Quantum Optics performed yet another experiment, this time using hydrogen atoms that had been excited by two different lasers. By measuring the energy required to excite hydrogen atoms from the 2S to the 2P state, the Rydberg constant could be calculated, and from this the proton radius inferred. The result is again ~5% smaller than the previously-accepted proton radius.[7][14] In 2019, another experiment reported a measurement of the proton size using a method that was independent of the Rydberg constant—its result, 0.833 femtometers, agreed with the smaller 2010 value once more.[15]

Proposed resolutions

The anomaly remains unresolved and is an active area of research. There is as yet no conclusive reason to doubt the validity of the old data.[7] The immediate concern is for other groups to reproduce the anomaly.[7]

The uncertain nature of the experimental evidence has not stopped theorists from attempting to explain the conflicting results. Among the postulated explanations are the three-body force,[16] interactions between gravity and the weak force, or a flavour-dependent interaction,[17][9] higher dimension gravity,[18] a new boson,[19] and the quasi-free Pion+ hypothesis.[lower-alpha 1]

Measurement artefact

Randolf Pohl, the original investigator of the puzzle, stated that while it would be "fantastic" if the puzzle led to a discovery, the most likely explanation is not new physics but some measurement artefact. His personal assumption is that past measurements have misgauged the Rydberg constant and that the current official proton size is inaccurate.[21]

Quantum chromodynamic calculation

In a paper by Belushkin et al. (2007),[22] including different constraints and perturbative quantum chromodynamics, a smaller proton radius than the then-accepted 0.877 femtometres was predicted.[22]

Proton radius extrapolation

Papers from 2016 suggested that the problem was with the extrapolations that had typically been used to extract the proton radius from the electron scattering data[23][24][25] though these explanation would require that there was also a problem with the atomic Lamb shift measurements.

Data analysis method

In one of the attempts to resolve the puzzle without new physics, Alarcón et al. (2018)[26] of Jefferson Lab have proposed that a different technique to fit the experimental scattering data, in a theoretically as well as analytically justified manner, produces a proton charge radius from the existing electron scattering data that is consistent with the muonic hydrogen measurement.[26] Effectively, this approach attributes the cause of the proton radius puzzle to a failure to use a theoretically motivated function for the extraction of the proton charge radius from the experimental data. Another recent paper has pointed out how a simple, yet theory motivated change to previous fits will also give the smaller radius.[27]

2019 measurements

In September 2019, Bezginov et al. reported the remeasurement of the proton's charge radius for electronic hydrogen and found a result consistent with Pohl's value for muonic hydrogen.[28] In November W. Xiong et al. reported a similar result using extremely low momentum transfer electron scattering.[29]

Their results support the smaller proton charge radius, but do not explain why the results before 2010 came out larger. It is likely future experiments will be able to both explain and settle the proton radius puzzle.[30]

2022 analysis

A re-analysis of experimental data, published in February 2022, found a result consistent with the smaller value of approximately 0.84 fm.[31][32]

Footnotes

  1. According to a report by Lestone (2017),[20] "Muonic hydrogen (μp) and muonic deuterium (μd) Lamb shifts can be obtained to better than 1% via simple methods. The smallness of the muon fuzziness suggests that the associated Lamb shifts need to be calculated including some aspects of the internal degrees of freedom of the proton. If the charge of the proton is assumed to be contained within a quasi-free Pion+ for half of the time, then the calculated μp and μd Lamb shifts are consistent with experiment without any need for a change in the proton radius. ... As a simple approximation, we here assume that the proton can be thought of as spending approximately half its time as a neutron with a nearby quasi-free Pion+ with an inertia of approximately 140 MeV."[20]

References

  1. Krauth, J. J.; Schuhmann, K.; Abdou Ahmed, M.; Amaro, F. D.; Amaro, P.; Biraben, F.; Cardoso, J. M. R.; Carvalho, M. L. et al. (2 June 2017). "The proton radius puzzle". 52nd Rencontres de Moriond EW 2017. La Thuile, Aosta Valley. Bibcode2017arXiv170600696K.  Presentation slides (19 March 2017).
  2. 2.0 2.1 2.2 "The size of the proton". Nature 466 (7303): 213–216. July 2010. doi:10.1038/nature09250. PMID 20613837. Bibcode2010Natur.466..213P. http://www.quantum.physik.uni-potsdam.de/teaching/ss2015/pqt/Pohl2010.pdf. 
  3. Hammer, Hans-Werner; Meißner, Ulf-G. (2020). "The proton radius: From a puzzle to precision". Science Bulletin 65 (4): 257–258. doi:10.1016/j.scib.2019.12.012. PMID 36659086. Bibcode2020SciBu..65..257H. http://inspirehep.net/record/1769185. 
  4. R.L. Workman et al. (Particle Data Group), Prog.Theor.Exp.Phys. 2022, 083C01 (2022), The Review of Particle Physics (2022), Particle listing - Proton, page 7: "the puzzle appears to be resolved."
  5. Karr, Jean-Philippe; Marchand, Dominique (2019). "Progress on the proton-radius puzzle". Nature 575 (7781): 61–62. doi:10.1038/d41586-019-03364-z. PMID 31695215. Bibcode2019Natur.575...61K. 
  6. Hill, Heather (6 November 2019). "Proton radius puzzle may be solved". Physics Today. doi:10.1063/PT.6.1.20191106a. ISSN 1945-0699. 
  7. 7.0 7.1 7.2 7.3 Davide Castelvecchi (5 October 2017). "Proton-size puzzle deepens". Nature. doi:10.1038/nature.2017.22760. http://www.nature.com/news/proton-size-puzzle-deepens-1.22760. 
  8. "Proton root-mean-square radii and electron scattering". Physical Review C 89 (1): 012201. 2014. doi:10.1103/PhysRevC.89.012201. Bibcode2014PhRvC..89a2201S. 
  9. 9.0 9.1 Zyga, Lisa (November 26, 2013). "Proton radius puzzle may be solved by quantum gravity". Phys.org. http://phys.org/news/2013-11-proton-radius-puzzle-quantum-gravity.html. 
  10. "The proton radius puzzle". Progress in Particle and Nuclear Physics 82: 59–77. May 2015. doi:10.1016/j.ppnp.2015.01.002. Bibcode2015PrPNP..82...59C. 
  11. "CODATA Internationally recommended 2014 values of the Fundamental Physical Constants: Proton RMS charge radius rp". http://physics.nist.gov/cgi-bin/cuu/Value?rp. 
  12. "Laser spectroscopy of muonic deuterium". Science 353 (6300): 669–673. 2016. doi:10.1126/science.aaf2468. PMID 27516595. Bibcode2016Sci...353..669P. 
  13. "Proton-radius puzzle deepens". CERN Courier. 16 September 2016. https://cerncourier.com/a/proton-radius-puzzle-deepens/. "After our first study came out in 2010, I was afraid some veteran physicist would get in touch with us and point out our great blunder. But the years have passed, and so far nothing of the kind has happened." 
  14. Beyer, Axel; Maisenbacher, Lothar; Matveev, Arthur; Pohl, Randolf; Khabarova, Ksenia; Grinin, Alexey; Lamour, Tobias; Yost, Dylan C. et al. (2017). "The Rydberg constant and proton size from atomic hydrogen". Science 358 (6359): 79–85. doi:10.1126/science.aah6677. PMID 28983046. Bibcode2017Sci...358...79B. 
  15. Bezginov, N.; Valdez, T.; Horbatsch, M.; Marsman, A.; Vutha, A. C.; Hessels, E. A. (5 September 2019). "A measurement of the atomic hydrogen Lamb shift and the proton charge radius". Science 365 (6457): 1007–1012. doi:10.1126/science.aau7807. PMID 31488684. Bibcode2019Sci...365.1007B. 
  16. Karr, J.; Hilico, L. (2012). "Why three-body physics does not solve the proton-radius puzzle". Physical Review Letters 109 (10): 103401. doi:10.1103/PhysRevLett.109.103401. PMID 23005286. Bibcode2012PhRvL.109j3401K. 
  17. Onofrio, R. (2013). "Proton radius puzzle and quantum gravity at the Fermi scale". EPL 104 (2): 20002. doi:10.1209/0295-5075/104/20002. Bibcode2013EL....10420002O. 
  18. Dahia, F.; Lemos, A.S. (2016). "Is the proton radius puzzle evidence of extra dimensions?". European Physical Journal 76 (8): 435. doi:10.1140/epjc/s10052-016-4266-7. Bibcode2016EPJC...76..435D. 
  19. "Electrophobic Scalar Boson and Muonic Puzzles". Physical Review Letters 117 (10): 101801. 2016. doi:10.1103/PhysRevLett.117.101801. PMID 27636468. Bibcode2016PhRvL.117j1801L. 
  20. 20.0 20.1 Lestone, J.P. (4 October 2017). Muonic atom Lamb shift via simple means (Report). Los Alamos Report. Los Alamos National Laboratory. LA-UR-17-29148. https://permalink.lanl.gov/object/tr?what=info:lanl-repo/lareport/LA-UR-18-29699. 
  21. Wolchover, Natalie (11 August 2016). "New measurement deepens proton puzzle". Quanta Magazine. https://www.quantamagazine.org/20160811-new-measurement-deepens-proton-radius-puzzle/. 
  22. 22.0 22.1 Belushkin, M.A.; Hammer, H.-W.; Meißner, Ulf-G. (2007). "Dispersion analysis of the nucleon form factors including meson continua". Physical Review C 75 (3): 035202. doi:10.1103/PhysRevC.75.035202. ISSN 0556-2813. Bibcode2007PhRvC..75c5202B. 
  23. Higinbotham, Douglas W.; Kabir, Al Amin; Lin, Vincent; Meekins, David; Norum, Blaine; Sawatzky, Brad (31 May 2016). "Proton radius from electron scattering data". Physical Review C 93 (5): 055207. doi:10.1103/PhysRevC.93.055207. Bibcode2016PhRvC..93e5207H. 
  24. Griffioen, Keith; Carlson, Carl; Maddox, Sarah (17 June 2016). "Consistency of electron scattering data with a small proton radius". Physical Review C 93 (6): 065207. doi:10.1103/PhysRevC.93.065207. Bibcode2016PhRvC..93f5207G. 
  25. Horbatsch, Marko; Hessels, Eric A.; Pineda, Antonio (13 March 2017). "Proton radius from electron-proton scattering and chiral perturbation theory". Physical Review C 95 (3): 035203. doi:10.1103/PhysRevC.95.035203. Bibcode2017PhRvC..95c5203H. 
  26. 26.0 26.1 Alarcón, J.M.; Higinbotham, D.W.; Weiss, C.; Ye, Zhihong (5 April 2019). "Proton charge radius extraction from electron scattering data using dispersively improved chiral effective field theory". Physical Review C 99 (4): 044303. doi:10.1103/PhysRevC.99.044303. Bibcode2019PhRvC..99d4303A. 
  27. Barcus, Scott K.; Higinbotham, Douglas W.; McClellan, Randall E. (10 July 2020). "How analytic choices can affect the extraction of electromagnetic form factors from elastic electron scattering cross section data". Physical Review C 102 (1): 015205. doi:10.1103/PhysRevC.102.015205. Bibcode2020PhRvC.102a5205B. 
  28. Bezginov, N.; Valdez, T.; Horbatsch, M.; Marsman, A.; Vutha, A. C.; Hessels, E. A. (2019). "A measurement of the atomic hydrogen Lamb shift and the proton charge radius". Science 365 (6457): 1007–1012. doi:10.1126/science.aau7807. ISSN 0036-8075. PMID 31488684. Bibcode2019Sci...365.1007B. 
  29. Xiong, W.; Gasparian, A.; Gao, H.; Dutta, D.; Khandaker, M. et al. (2019). "A small proton charge radius from an electron–proton scattering experiment". Nature 575 (7781): 147–150. doi:10.1038/s41586-019-1721-2. ISSN 0028-0836. PMID 31695211. Bibcode2019Natur.575..147X. 
  30. Karr, Jean-Philippe; Marchand, Dominique (2019). "Progress on the proton-radius puzzle". Nature 575 (7781): 61–62. doi:10.1038/d41586-019-03364-z. ISSN 0028-0836. PMID 31695215. Bibcode2019Natur.575...61K. 
  31. Lin, Yong-Hui; Hammer, Hans-Werner; Meißner, Ulf-G. (2022-02-03). "New Insights into the Nucleon's Electromagnetic Structure" (in en). Physical Review Letters 128 (5): 052002. doi:10.1103/PhysRevLett.128.052002. ISSN 0031-9007. PMID 35179940. Bibcode2022PhRvL.128e2002L. https://link.aps.org/doi/10.1103/PhysRevLett.128.052002. 
  32. "Protons are probably actually smaller than long thought" (in en). https://www.uni-bonn.de/en/news/020-2022. 



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