A small proton charge radius from an electron–proton scattering experiment

Xiong, Weizhi; Gasparian, A.; H, Gao; Dutta, D.; Khandaker, M.; Liyanage, N.; Pasyuk, E.; Peng, C.; Bai, X.; Ye, L.; Gnanvo, K.; Gu, C.; Levillain, M.; Yan, X.; Higinbotham, D. W.; Meziane, M.; Ye, Z.; Adhikari, K. P.; Aljawrneh, B.; Bhatt, H.; Bhetuwal, D.; Brock, J.; Burkert, Volker; Carlin, C.; Deur, A.; Di, D.; Dunne, J.; Ekanayaka, Pubuduni; El-Fassi, L.; Emmich, B.; Gan, L.; Glamazdin, O.; Kabir, Latiful; Karki, A.; Keith, C.; Kowalski, S.; Lagerquist, V.; Larin, I.; Liu, Tianbo; Liyanage, A.; Maxwell, James; Meekins, D.; Nazeer, S. J.; Nelyubin, V.; Nguyen, H.; Pedroni, R.; Perdrisat, C. F.; Pierce, J.; Punjabi, V.; Shabestari, M.; Shahinyan, A.; Silwal, R.; Stepanyan, S.; Subedi, A.; Tarasov, V. V.; Ton, N.; Zhang, Y.; Zhao, Zhiwen

doi:10.1038/s41586-019-1721-2

Cited by 294 publications

(286 citation statements)

References 31 publications

(35 reference statements)

Supporting

Mentioning

243

Contrasting

Unclassified

Order By: Relevance

“…2 shows that the radius depends almost linearly on a and reveals that the original value of r E can be reproduced if a, determined in the first step of our analysis, is used, but with the opposite (wrong) sign. To confirm this hypothesis, we again fitted model (2) to the data with Q 2 < 1.05 fm −2 , but this time kept the radius fixed at 0.805 (11) fm and adjusted only a. We obtained a = −0.00749(63) fm 4 , which strongly supports our assumption that a mistake was made in the original analysis.…”

Section: Introductionsupporting

confidence: 56%

“…The result of this work compared to other extractions of the proton charge radius. Full circles show findings of modern nuclear scattering experiments ( [11,[32][33][34]) together with the original result of Hand et al [2]. Full squares represent values obtained from the recent atomic hydrogen spectroscopy measurements ( [9,10,12]).…”

Section: Discussionmentioning

confidence: 99%

“…and can be determined by both hydrogen spectroscopy and elastic lepton scattering [1]. The first determination of the radius was done with elastic electron scattering data by Hand et al [2], who determined the radius of 0.805 (11) fm, the value used in the standard dipole parameterization of the form factor [3,4]. The original study was followed by several decades of dedicated nuclear scattering and spectroscopic experiments, which led to a recommended value for the proton charge radius of 0.8791(79) fm (CODATA 2010, [5]).…”

Section: Introductionmentioning

confidence: 99%

“…This result was called into question when the extremely precise spectroscopic measurements on muonic hydrogen [6,7] reported a significantly smaller value of 0.84087 (39) fm. The observed discrepancy, colloquially known as "the proton radius puzzle" [8] motivated several new experiments [9][10][11][12]. These experiments have been accompanied by different reanalyses of the existing data [13][14][15][16][17][18][19][20], focusing on data of Bernauer et al [21,22].…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Reinterpretation of Classic Proton Charge Form Factor Measurements

et al. 2020

View full text Add to dashboard Cite

In 1963, a proton radius of 0.805(11) fm was extracted from electron scattering data and this classic value has been used in the standard dipole parameterization of the form factor. In trying to reproduce this classic result, we discovered that there was a sign error in the original analysis and that the authors should have found a value of 0.851(19) fm. We additionally made use of modern computing power to find a robust function for extracting the radius using this 1963 data's spacing and uncertainty. This optimal function, the Padé (0, 1) approximant, also gives a result which is consistent with the modern high precision proton radius extractions. ⋆

show abstract

Section: Introductionsupporting

confidence: 56%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Reinterpretation of Classic Proton Charge Form Factor Measurements

et al. 2020

View full text Add to dashboard Cite

show abstract

“…Lamb shift [17] 0.833 (10) 2019 el. Lamb shift [18] 0.831(7)(12) 2019 e − p scattering [19] a small radius in the range r p = 0.82 . .…”

mentioning

confidence: 99%

The proton radius: from a puzzle to precision

Hammer

Meißner

2020

Science Bulletin

View full text Add to dashboard Cite

show abstract

Complex Oxides for Brain‐Inspired Computing: A Review

et al. 2022

View full text Add to dashboard Cite

The fields of brain‐inspired computing, robotics, and, more broadly, artificial intelligence (AI) seek to implement knowledge gleaned from the natural world into human‐designed electronics and machines. In this review, the opportunities presented by complex oxides, a class of electronic ceramic materials whose properties can be elegantly tuned by doping, electron interactions, and a variety of external stimuli near room temperature, are discussed. The review begins with a discussion of natural intelligence at the elementary level in the nervous system, followed by collective intelligence and learning at the animal colony level mediated by social interactions. An important aspect highlighted is the vast spatial and temporal scales involved in learning and memory. The focus then turns to collective phenomena, such as metal‐to‐insulator transitions (MITs), ferroelectricity, and related examples, to highlight recent demonstrations of artificial neurons, synapses, and circuits and their learning. First‐principles theoretical treatments of the electronic structure, and in situ synchrotron spectroscopy of operating devices are then discussed. The implementation of the experimental characteristics into neural networks and algorithm design is then revewed. Finally, outstanding materials challenges that require a microscopic understanding of the physical mechanisms, which will be essential for advancing the frontiers of neuromorphic computing, are highlighted.

show abstract

A small proton charge radius from an electron–proton scattering experiment

Cited by 294 publications

References 31 publications

Reinterpretation of Classic Proton Charge Form Factor Measurements

Reinterpretation of Classic Proton Charge Form Factor Measurements

The proton radius: from a puzzle to precision

Complex Oxides for Brain‐Inspired Computing: A Review

Contact Info

Product

Resources

About