Generalized Parton Distributions of proton for nonzero skewness in transverse and longitudinal position spaces

We investigate the Generalized Parton Distributions (GPDs) of proton by expressing them in terms of overlaps of light front wave functions (LFWFs) using a simulated model which is able to qualitatively improve the convergence near the end points of x. We study the spin nonflip H(x, ζ, t) and spin flip E(x, ζ, t) parts of GPDs for the particle conserving n → n overlap in the DGLAP region (ζ < x < 1). The Fourier transform (FT) of the GPDs with respect to the transverse momentum transfer as well as the FT of the GPDs with respect to ζ has also been obtained by giving the distribution of partons in the transverse position space and the distribution in the longitudinal position space, respectively. Diffraction pattern is obtained for both [Formula: see text] and [Formula: see text] in the longitudinal position space.

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NONTRIVIAL RELATIONS BETWEEN GPDs AND TMDs>

Modern Physics Letters A ◽

10.1142/s0217732309001182 ◽

2009 ◽

Vol 24 (35n37) ◽

pp. 2973-2983 ◽

Cited By ~ 3

Author(s):

ANDREAS METZ ◽

STEPHAN MEISSNER ◽

MARC SCHLEGEL

Keyword(s):

Transverse Momentum ◽

Present Knowledge ◽

The Other ◽

Parton Distributions ◽

Transverse Momentum Dependent ◽

Generalized Parton Distributions ◽

Model Independent ◽

The One

The present knowledge about nontrivial relations between generalized parton distributions for a spin-1/2 hadron on the one hand and transverse momentum dependent distributions on the other is reviewed. While various relations can be found in the framework of simple spectator models, so far no model-independent nontrivial relations have been established. In fact, by relating the two types of parton distributions to the fully unintegrated, off-diagonal quark-quark correlator for a spin-1/2 hadron, we argue that none of the nontrivial relations can be promoted to a model-independent status.

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Tunable fractional Fourier transform implementation of electronic wave functions in atomically thin materials

Beilstein Journal of Nanotechnology ◽

10.3762/bjnano.9.174 ◽

2018 ◽

Vol 9 ◽

pp. 1828-1833 ◽

Cited By ~ 1

Author(s):

Daniela Dragoman

Keyword(s):

Wave Function ◽

Fourier Transform ◽

Fractional Fourier Transform ◽

Berry Phase ◽

Wave Functions ◽

Electron Propagation ◽

One Step ◽

The Difference ◽

Integrated Logic ◽

The Fourier Transform

A tunable fractional Fourier transform of the quantum wave function of electrons satisfying either the Schrödinger or the Dirac equation can be implemented in an atomically thin material by a parabolic potential distribution applied on a direction transverse to that of electron propagation. The difference between the propagation lengths necessary to obtain a fractional Fourier transform of a given order in these two cases could be seen as a manifestation of the Berry phase. The Fourier transform of the electron wave function is a particular case of the fractional Fourier transform. If the input and output wave functions are discretized, this configuration implements in one step the discrete fractional Fourier transform, in particular the discrete Fourier transform, and thus can act as a coprocessor in integrated logic circuits.

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THE SPIN STRUCTURE OF THE NUCLEON IN LIGHT-CONE QUARK MODELS

Modern Physics Letters A ◽

10.1142/s021773230900111x ◽

2009 ◽

Vol 24 (35n37) ◽

pp. 2903-2912 ◽

Cited By ~ 14

Author(s):

B. PASQUINI ◽

S. BOFFI ◽

P. SCHWEITZER

Keyword(s):

Transverse Momentum ◽

Light Cone ◽

Parton Distributions ◽

Transverse Momentum Dependent ◽

Spin Asymmetries ◽

Generalized Parton Distributions ◽

Quark Spin ◽

Quark Models ◽

Impact Parameter Space

The quark spin densities related to generalized parton distributions in impact-parameter space and to transverse-momentum dependent parton distributions are reviewed within a light-cone quark model, with focus on the role of the different spin-spin and spin-orbit correlations of quarks. Results for azimuthal spin asymmetries in semi-inclusive deep inelastic scattering due to T -even transverse-momentum dependent parton distributions are also discussed.

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Power-law wave functions and generalized parton distributions for the pion

Physical Review D ◽

10.1103/physrevd.67.073014 ◽

2003 ◽

Vol 67 (7) ◽

Cited By ~ 38

Author(s):

A. Mukherjee ◽

I. V. Musatov ◽

H. C. Pauli ◽

A. V. Radyushkin

Keyword(s):

Power Law ◽

Wave Functions ◽

Parton Distributions ◽

Generalized Parton Distributions

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Generalized Parton Distributions for the Proton in Position Space

Journal of Physics Conference Series ◽

10.1088/1742-6596/295/1/012071 ◽

2011 ◽

Vol 295 ◽

pp. 012071

Author(s):

R Manohar ◽

A Mukherjee ◽

D Chakrabarti

Keyword(s):

Position Space ◽

Parton Distributions ◽

Generalized Parton Distributions

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Preferred Orientation, PDF and Debye Equation

Acta Crystallographica Section A Foundations and Advances ◽

10.1107/s2053273314089220 ◽

2014 ◽

Vol 70 (a1) ◽

pp. C1077-C1077

Author(s):

Reinhard Neder

Keyword(s):

Fourier Transform ◽

Diffraction Pattern ◽

Complex Function ◽

Good Alternative ◽

Preferred Orientation ◽

Spherical Average ◽

Area Detector ◽

Orientation Axis ◽

The Fourier Transform ◽

Debye Equation

The effect of preferred orientation is currently neglected in the Debye Equation and PDF calculations. This is to a large extend justified, especially for the PDF, as the scattering by large sample volumes is detected by an area detector. The integration of powder rings reduces the effects of preferred orientation. As more laboratory PDF measurements become available that use linear position sensitive detectors or single counter detectors, preferred orientation needs to be reconsidered. A Rietveld calculation treats preferred orientation by multiplying the Bragg intensity by a factor that depends on the angle between the reciprocal space vector and the preferred orientation axis. The powder intensity I(Q) is thus multiplied by a complex function that depends at each Q on the degree of preferred orientation, the lattice parameters, reflection multiplicity etc. The effect on the PDF is therefore the convolution by the Fourier transform of this complex function. The Debye equation is derived from a spherical average of the scattering intensity of a finite object. Thus completely random orientation of the powder grains is implicitly assumed. Both, the Debye algorithm and the PDF algorithm calculate the powder pattern, respectively the PDF from a histogram of interatomic distances, which correspond to a spherical average of all interatomic distance vectors. This histogram does not allow for a Rietveld preferred orientation correction. The effects of preferred orientation on the PDF will be presented on the basis of simulated diffraction pattern. An algorithm to describe the changes in the PDF and the inverse sine Fourier transform as a convenient tool to calculate the powder diffraction pattern will be introduced. This is a good alternative to the Debye equation and allows to take preferred orientation into account both for the PDF and the calculated powder.

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