EMC effect in the next-to-leading order approximation based on the Laplace transformation

Sheibani, Javad; Mirjalili, A.; Tehrani, S. Atashbar

doi:10.1103/physrevc.98.045211

Cited by 7 publications

(1 citation statement)

References 51 publications

(132 reference statements)

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“…In Refs. [28] and [39], the application of Laplace transform technique to the analysis of charged-current structure functions xF 3 (x, Q 2 ) as well as the EMC effects are studied. The spin-dependent structure functions xg p 1 (x, Q 2 ) are analyzed via the same technique in Refs.…”

Section: Nnlo Nonsinglet Solution In Laplace Spacementioning

confidence: 99%

QCD analysis of non-singlet structure functions at NNLO accuracy, based on the Laplace transform

Nejad¹,

Salajegheh²,

Mirjalili³

et al. 2020

Eur. Phys. J. Plus

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In this work, using the Laplace transformation technique we present our results for nonsinglet quark distributions as well as nucleon structure function F2(x, Q 2 ) in unpolarized case at next-tonext-to-leading order (NNLO) QCD approximation. We shall particularly compare our results for the sets of valence-quark parton distribution functions with the contemporary collaborations like CT14, MMHT14, MKAM16 and NNPDF groups. In our analysis, to construct the nucleon structure function we employ the Jacobi polynomials expansion which is suitable to convert the results for nonsinglet structure function from the Laplace s-space to Bjorken x-space. We shall also consider the contributions of target mass correction as well as the higher twist effects at large x region for the proton and deuteron structure function. Our results for the unpolarized quark distribution functions and nucleon structure functions are in good agreement with both recent theoretical models and available experimental data.

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Section: Nnlo Nonsinglet Solution In Laplace Spacementioning

confidence: 99%

QCD analysis of non-singlet structure functions at NNLO accuracy, based on the Laplace transform

Nejad¹,

Salajegheh²,

Mirjalili³

et al. 2020

Eur. Phys. J. Plus

Self Cite

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Parton and Valon Distributions in the Nuclei

2020

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Ratio of the structure functions and the color dipole model bound

Boroun

Rezaei

2019

Nuclear Physics A

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We observe that the DGLAP evolution equations at NNLO analysis predicts a ratio of the structure functions in region of small Bjorken variable x. The ratio FL(x, Q 2 )/F2(x, Q 2 ) is obtained and compared with the prediction of the dipole model and HERA data. In particular we show that this ratio is lower than dipole model bound at high-Q 2 values and it is higher at low-Q 2 values . Then the effect of adding a higher twist term to the description of the ratio FL(x, Q 2 )/F2(x, Q 2 ) for Q 2 < 20 GeV 2 is investigated. Also the bounds are discussed by including charm distribution on FL/F2. We discuss, furthermore, how this ratio can be determine the proton structure function with respect to the reduced cross section at high-y values.

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EMC effect in the next-to-leading order approximation based on the Laplace transformation

Cited by 7 publications

References 51 publications

QCD analysis of non-singlet structure functions at NNLO accuracy, based on the Laplace transform

QCD analysis of non-singlet structure functions at NNLO accuracy, based on the Laplace transform

Parton and Valon Distributions in the Nuclei

Ratio of the structure functions and the color dipole model bound

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