The Dirac form factor predicts the Pauli form factor in the Endpoint Model

Dagaonkar, Sumeet; Jain, Pankaj; Ralston, John P.

doi:10.1140/epjc/s10052-016-4224-4

Cited by 6 publications

(6 citation statements)

References 45 publications

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“…This rule is predicted by the hard scattering mechanism [24], but not observed in data. It also naturally leads to the prediction, F 2 /F 1 ∝ 1/Q [25], in agreement with data, while the short distance model would predict F 2 /F 1 ∝ 1/Q 2 . Furthermore, it does not predict the phenomenon of color transparency, at least in its simplest form, and hence is nicely consistent with experimental results [8][9][10][11][12].…”

Section: B More About the Endpoint Processsupporting

confidence: 82%

The Status and Future of Color Transparency and Nuclear Filtering

Jain¹,

Pire²,

Ralston³

2022

Preprint

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40 years after its introduction, the phenomenon of color transparency remains a domain of controversial interpretations of experimental data. We review present evidence for or against its manifestation in various exclusive hard scattering reactions. The nuclear transparency experiments reveal whether short distance processes dominate a scattering amplitude at some given kinematical point. We plead for a new round of nuclear transparency measurements in a variety of experimental set-ups, including near-forward exclusive reactions related to generalized parton distribution (GPD) physics and near-backward exclusive reactions related to transition distribution amplitudes (TDA) physics.

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Section: B More About the Endpoint Processsupporting

confidence: 82%

The Status and Future of Color Transparency and Nuclear Filtering

Jain¹,

Pire²,

Ralston³

2022

Preprint

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“…[4]). The importance of the Sudakov suppression of some delicate integration regions was in particular discovered [48], which in turn may help to understand the suppression of endpoint region contributions for meson and baryon form factors [49,50] (for an alternative point of view, see [51,52]). Moreover, the absence of pinch singularities, which is a necessary element of the proof of factorization, was shown in [53] for the scattering amplitude for electroproduction processes at fixed angle, putting on a firm ground the collinear factorized framework for various processes.…”

Section: Electromagnetic Form Factors and Distribution Amplitudesmentioning

confidence: 99%

Transition distribution amplitudes and hard exclusive reactions with baryon number transfer

Pire,

Semenov-Tian-Shansky,

Szymanowski

2021

Preprint

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Baryon-to-meson and baryon-to-photon transition distribution amplitudes (TDAs) arise in the collinear factorized description of a class of hard exclusive reactions characterized by the exchange of a non-zero baryon number in the cross channel. These TDAs extend the concepts of generalized parton distributions (GPDs) and baryon distribution amplitudes (DAs). In this review we discuss the general properties and physical interpretation of baryon-to-meson and baryon-to-photon TDAs. We argue that these nonperturbative objects are a convenient complementary tool to explore the structure of baryons at the partonic level. We present an overview of hard exclusive reactions admitting a description in terms of TDAs. We discuss the first signals from hard exclusive backward meson electroproduction at JLab with the 6 GeV electron beam and explore further experimental opportunities to access TDAs at JLab@12 GeV, PANDA and J-PARC.

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“…In the above diagrams, the incoming proton is understood to be deflected by q µ = (0, Q, 0, 0), where q µ = q µ 1 − q µ 2 . This allows us to use the same frame and kinematics for the proton, as was used for the analysis of Dirac and Pauli form factors [14,15] with q = (0, Q, 0, 0), P = ( Q 2 /2 + M 2 P , −Q/2, 0, Q/2), P = ( Q 2 /2 + M 2 P , Q/2, 0, Q/2). We can choose q 1 , q 2 appropriately so that θ cm ∈ [64 • , 130 • ], which is the range of the data obtained at Jlab [3].…”

Section: Kinematicsmentioning

confidence: 99%

Section: Kinematicsmentioning

confidence: 99%

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Compton scattering in the Endpoint Model

Dagaonkar

2018

Eur. Phys. J. C

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We use the Endpoint model for exclusive hadronic processes to study Compton scattering of the proton. The parameters of the Endpoint model are fixed using the data for F1 and the ratio of Pauli and Dirac form factors (F2/F1) and then used to get numerical predictions for the differential scattering cross section. We studied the Compton scattering at fixed θCM in the s ∼ t ΛQCD limit and at fixed s much larger than t limit. We observed that the calculations in the Endpoint Model give a good fit with experimental data in both regions. * sumeetkd@iitk.ac.in

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The Dirac form factor predicts the Pauli form factor in the Endpoint Model

Cited by 6 publications

References 45 publications

The Status and Future of Color Transparency and Nuclear Filtering

The Status and Future of Color Transparency and Nuclear Filtering

Transition distribution amplitudes and hard exclusive reactions with baryon number transfer

Compton scattering in the Endpoint Model

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