The quantum phase-space formalism derives transverse energy-momentum tensor distributions in polarized nucleons and reproduces standard light-front distributions including bad components in the infinite-momentum frame.
Defining the Proton Radius: a Unified Treatment
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
Background: There is significant current interest in knowing the value of the proton radius and also its proper definition. Purpose: Combine the disparate literatures of hydrogen spectroscopy and diverse modern parton distributions to show that the quantity $r_p^2\equiv -6 G_E'(0)$ is the relativistically proper definition that originates from the separate bodies of work. Methods: Use perturbation theory, light-front dynamics and elementary techniques to find relativistically correct definitions of the proton radius and charge density. Results: It is found that the very same proton radius is accessed by measurements of hydrogen spectroscopy and elastic lepton scattering. The derivation of the mean-square radius as a moment of a spherically symmetric three-dimensional density is shown to be incorrect. A relativistically-correct, two-dimensional charge density is related to the diverse modern literature of various parton distributions. Relativistically invariant moments thereof are derived in a new moment expansion, the RME.
citation-role summary
citation-polarity summary
fields
hep-ph 2years
2026 2verdicts
UNVERDICTED 2roles
background 1polarities
background 1representative citing papers
A modified non-separable LFWF ansatz for pseudoscalar heavy quarkonia enables computation of zero-skewness GPDs, EM and gravitational form factors, and transverse distributions within the Schwinger-function framework.
citing papers explorer
-
Transverse energy-momentum tensor distributions in polarized nucleons
The quantum phase-space formalism derives transverse energy-momentum tensor distributions in polarized nucleons and reproduces standard light-front distributions including bad components in the infinite-momentum frame.
-
Pseudoscalar charmonium and bottomonium: light-front wave functions, distribution amplitudes and distribution functions
A modified non-separable LFWF ansatz for pseudoscalar heavy quarkonia enables computation of zero-skewness GPDs, EM and gravitational form factors, and transverse distributions within the Schwinger-function framework.