Physicists Baffled by Proton Structure Anomaly HEAD TOPICS

Physicists Baffled by Proton Structure Anomaly

10/22/2022 7:45:00 PM

Physicists Baffled by Proton Structure Anomaly

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SciTechDaily

Physicists Baffled by Proton Structure Anomaly Precision measurement of how a proton’s structure deforms in an electric field has revealed new details about an unexplained spike in proton data. Nuclear physicists have confirmed that the current description of proton structure isn’t perfect. A bump in the data in probes of the proton’s structu Precision measurement of how a proton’s structure deforms in an electric field has revealed new details about an unexplained spike in proton data..Measurements of the proton’s electric polarizability reveal how susceptible the proton is to deformation, or stretching, in an electric field, according to Ruonan Li, first author on the new paper and a graduate student at Temple University. Like size or charge, the electric polarizability is a fundamental property of proton structure. The real photon that is produced in the virtual Compton scattering reaction provides the electromagnetic perturbation to the proton and allows to measure its electromagnetic generalized polarizabilities. Credit: Image courtesy of Nikos Sparveris, Temple University Read more:
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Toyota Motor Corp said on Friday its annual vehicle production was likely to come in below its initial target, as a persistent global semiconductor shortage hampers efforts by the world's biggest car maker by sales to boost output. Read more >> Measured proton electromagnetic structure deviates from theoretical predictions - NatureMeasurements of the proton’s electromagnetic structure show enhancement of its electric generalized polarizability compared with theoretical expectations, confirming the presence of a new dynamical mechanism not accounted for by current theories. Engadget Podcast: Apple's confusing new iPads EngadgetThis week, we discuss Apple's baffling new base iPad and the new iPad Pro with M2.. Not sure what's confusing about them, they upgraded the chips in them, it's a new line. Seems simple enough. Entire Car Discovered Buried Under California Mansion’s DrivewayPolice were working into the night after landscapers uncovered an entire car buried in the concrete driveway of a California mansion. morgfair morgfair Oh oh Check the trunk Did you see these lights over the Coast last night?Some took to social media claiming they just saw a UFO, while others were simply baffled. Firefighters Battle Structure Fire in ConcordFirefighters on Friday were working to put out a structure fire in Concord. Fire in Provo neighborhood leaves one person dead, another injuredBREAKING: Crews, police responding to a structure fire in Provo near 1000 N. and 1600 W. We have further details about the incident, and we're awaiting confirmation from authorities. We're updating this article as we get and confirm information. Police have confirmed that at least one person is dead as a result of the fire. We're working to confirm additional information. Thomas Jefferson National Laboratory October 22, 2022 A new precision measurement of the proton’s electric polarizability has confirmed the presence of an anomaly, raising questions about its origin.Download references Acknowledgements WE would like to thank M.Subscribe! Apple just dropped several new devices on us this week, seemingly out of nowhere.12:50AM ET D-Keine/Getty Police were working into the night after landscapers uncovered an entire car buried in the concrete driveway of a California mansion Thursday morning. Precision measurement of how a proton’s structure deforms in an electric field has revealed new details about an unexplained spike in proton data. Nuclear physicists have confirmed that the current description of proton structure isn’t perfect. This work has been supported by the US Department of Energy Office of Science, Office of Nuclear Physics under contract nos. A bump in the data in probes of the proton’s structure has been revealed by a new precision measurement of the proton’s electric polarizability performed at the U. (At least the new Apple TV 4K seems likely a genuinely solid upgrade.S. Author information Temple University, Philadelphia, PA, USA R. Department of Energy’s Thomas Jefferson National Accelerator Facility. When this was seen in earlier measurements, it was widely thought to be a fluke. Sparveris, H. However, this new, more precise measurement has confirmed the presence of the anomaly and raises important questions about its origin. The research was published on October 19 in the journal Nature . Boer, B. “There is something that we’re clearly missing at this point. The proton is the only composite building block in nature that is stable. Jia & M. So, if we are missing something fundamental there, it has implications or consequences for all of physics.” — Nikos Sparveris Measurements of the proton’s electric polarizability reveal how susceptible the proton is to deformation, or stretching, in an electric field, according to Ruonan Li, first author on the new paper and a graduate student at Temple University. K. Like size or charge, the electric polarizability is a fundamental property of proton structure. What’s more, a precision determination of the proton’s electric polarizability can help bridge the different descriptions of the proton. Camsonne, J. Depending on how it is probed, a proton may appear as an opaque single particle or as a composite particle made of three quarks held together by the strong force. “We want to understand the substructure of the proton. Chen, M. And we can imagine it like a model with the three balanced quarks in the middle,” Li explained. “Now, put the proton in the electric field. Gaskell, O. The quarks have positive or negative charges. They will move in opposite directions. Henry, S. So, the electric polarizability reflects how easily the proton will be distorted by the electric field.” The real photon that is produced in the virtual Compton scattering reaction provides the electromagnetic perturbation to the proton and allows to measure its electromagnetic generalized polarizabilities. McCaughan, B. Credit: Image courtesy of Nikos Sparveris, Temple University Nuclear physicists used a process called virtual Compton scattering to probe this distortion. This process starts with a carefully controlled beam of energetic electrons from Jefferson Lab’s Continuous Electron Beam Accelerator Facility, a DOE Office of Science user facility. R. The electrons are sent crashing into protons. In virtual Compton scattering, electrons interact with other particles by emitting an energetic photon, or particle of light. Paolone University of Virginia, Charlottesville, VA, USA Z. The energy of the electron determines the energy of the photon it emits, which also determines how the photon interacts with other particles. The Strong Nuclear Force (also called the strong force) is one of the four fundamental forces in nature (the others being gravity, the electromagnetic force, and the weak nuclear force). Zheng The College of William and Mary, Williamsburg, VA, USA C. It is the strongest of the four, as its name suggests. However, it also has the shortest range, meaning that particles must be extremely close before its effects are felt. B. Its primary function is to hold together the subatomic particles of the nucleus (protons, which carry a positive charge, and neutrons, which carry no charge. These particles are collectively called nucleons). Berdnikov, T. Lower energy photons may bounce off the surface of the proton, while more energetic photons will blast inside the proton to interact with one of its quarks. Theory predicts that when these photon-quark interactions are plotted at from lower to higher energies, they will form a smooth curve. Muhoza & R. Nikos Sparveris, an associate professor of physics at Temple University and spokesperson for the experiment, said this simple picture didn’t hold up to scrutiny. The measurements instead revealed an as-yet-unexplained bump. Biswas & A. “What we see is that there is some local enhancement to the magnitude of the polarizability. The polarizability decreases as the energy increases as expected. Liyanage Virginia Polytechnic Institute & State University, Blacksburg, VA, USA D. And, at some point, it appears to be coming temporarily up again before it will go down,” he said. “Based on our current theoretical understanding, it should follow a very simple behavior. Boer Mississippi State University, Mississippi State, MS, USA D. We see something that deviates from this simple behavior. And this is the fact that is puzzling us at the moment. Karki Old Dominion University, Norfolk, VA, USA F.” The theory predicts that the more energetic electrons are more directly probing the strong force as it binds the quarks together to make the proton. This weird spike in the stiffness that nuclear physicists have now confirmed in the proton’s quarks signals that an unknown facet of the strong force may be at work. Heinrich, G. “There is something that we’re clearly missing at this point. The proton is the only composite building block in nature that is stable. Huber, S. So, if we are missing something fundamental there, it has implications or consequences for all of physics,” Sparveris confirmed. The physicists said that the next step is to further tease out the details of this anomaly and conduct precision probes to check for other points of deviation and to provide more information about the anomaly’s source. D. “We want to measure more points at various energies to present a clearer picture and to see if there is any further structure there,” Li said. Sparveris agreed. Kumar Argonne National Laboratory, Lemont, IL, USA S. “We also need to measure precisely the shape of this enhancement. The shape is important to further elucidating the theory,” he said.-E. Reference: “Measured proton electromagnetic structure deviates from theoretical predictions” by R. Li, N. Li, A. Sparveris, H. Atac, M. Zhou Florida International University, University Park, FL, USA P. K. Jones, M. Yero Artem Alikhanian National Laboratory, Yerevan, Armenia H. Paolone, Z. Akbar, C. Morean Veer Kunwar Singh University, Arrah, India A. Ayerbe Gayoso, V. Berdnikov, D. Pasquini Istituto Nazionale di Fisica Nucleare (INFN), Pavia, Italy B. Biswas, M. Boer, A. Camsonne, J. -P. Chen, M. Diefenthaler, B. Duran, D. Dutta, D. Gaskell, O. Hansen, F. Hauenstein, N. Heinrich, W. Henry, T. Horn, G. M. Huber, S. Jia, S. Joosten, A. Karki, S. J. D. Kay, V. Kumar, X. Li, W. B. Li, A. H. Liyanage, S. Malace, P. Markowitz, M. McCaughan, Z.-E. Meziani, H. Mkrtchyan, C. Morean, M. Muhoza, A. Narayan, B. Pasquini, M. Rehfuss, B. Sawatzky, G. R. Smith, A. Smith, R. Trotta, C. Yero, X. Zheng and J. Zhou, 19 October 2022, Nature .