Applications of a nonlinear evolution equation II: The EMC effect

Xurong Chen; Jianhong Ruan; Rong Wang; Pengming Zhang; Wei Zhu

doi:10.1142/S021830131450058X

Applications of a nonlinear evolution equation II: The EMC effect

Xurong Chen
, Jianhong Ruan
, Rong Wang
, Pengming Zhang
, Wei Zhu^*

^*Corresponding author for this work

School of Physics and Electronic Science

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

The EMC effect is studied by using the DGLAP equation with the ZRS corrections and minimum number of free parameters, where the nuclear shadowing effect is a dynamical evolution result of the equation, the nucleon swelling and Fermi motion in the nuclear environment deform the input parton distributions. Parton distributions of both proton and nucleus are predicted in a unified framework. We show that the parton recombination as a higher twist correction plays an essential role in the evolution of parton distributions either of proton or nucleus. We find that the nuclear anti-shadowing contributes a part of enhancement of the ratio of the structure functions around x ∼ 0.1, while the other part origins from the deformation of the nuclear valence quark distributions. In particular, the nuclear gluon distributions are dynamically predicted, which are important information for the recherche of the high energy nuclear physics.

Original language	English
Article number	1450058
Journal	International Journal of Modern Physics E
Volume	23
Issue number	10
DOIs	https://doi.org/10.1142/S021830131450058X
State	Published - 30 Oct 2014

Keywords

EMC effect
Nonlinear corrections
Nuclear shadowing and anti-shadowing
QCD evolution equation

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title = "Applications of a nonlinear evolution equation II: The EMC effect",

abstract = "The EMC effect is studied by using the DGLAP equation with the ZRS corrections and minimum number of free parameters, where the nuclear shadowing effect is a dynamical evolution result of the equation, the nucleon swelling and Fermi motion in the nuclear environment deform the input parton distributions. Parton distributions of both proton and nucleus are predicted in a unified framework. We show that the parton recombination as a higher twist correction plays an essential role in the evolution of parton distributions either of proton or nucleus. We find that the nuclear anti-shadowing contributes a part of enhancement of the ratio of the structure functions around x ∼ 0.1, while the other part origins from the deformation of the nuclear valence quark distributions. In particular, the nuclear gluon distributions are dynamically predicted, which are important information for the recherche of the high energy nuclear physics.",

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T1 - Applications of a nonlinear evolution equation II

T2 - The EMC effect

AU - Chen, Xurong

AU - Ruan, Jianhong

AU - Wang, Rong

AU - Zhang, Pengming

AU - Zhu, Wei

N1 - Publisher Copyright: © World Scientific Publishing Company.

PY - 2014/10/30

Y1 - 2014/10/30

N2 - The EMC effect is studied by using the DGLAP equation with the ZRS corrections and minimum number of free parameters, where the nuclear shadowing effect is a dynamical evolution result of the equation, the nucleon swelling and Fermi motion in the nuclear environment deform the input parton distributions. Parton distributions of both proton and nucleus are predicted in a unified framework. We show that the parton recombination as a higher twist correction plays an essential role in the evolution of parton distributions either of proton or nucleus. We find that the nuclear anti-shadowing contributes a part of enhancement of the ratio of the structure functions around x ∼ 0.1, while the other part origins from the deformation of the nuclear valence quark distributions. In particular, the nuclear gluon distributions are dynamically predicted, which are important information for the recherche of the high energy nuclear physics.

AB - The EMC effect is studied by using the DGLAP equation with the ZRS corrections and minimum number of free parameters, where the nuclear shadowing effect is a dynamical evolution result of the equation, the nucleon swelling and Fermi motion in the nuclear environment deform the input parton distributions. Parton distributions of both proton and nucleus are predicted in a unified framework. We show that the parton recombination as a higher twist correction plays an essential role in the evolution of parton distributions either of proton or nucleus. We find that the nuclear anti-shadowing contributes a part of enhancement of the ratio of the structure functions around x ∼ 0.1, while the other part origins from the deformation of the nuclear valence quark distributions. In particular, the nuclear gluon distributions are dynamically predicted, which are important information for the recherche of the high energy nuclear physics.

KW - EMC effect

KW - Nonlinear corrections

KW - Nuclear shadowing and anti-shadowing

KW - QCD evolution equation

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DO - 10.1142/S021830131450058X

M3 - 文章

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SN - 0218-3013

VL - 23

JO - International Journal of Modern Physics E

JF - International Journal of Modern Physics E

IS - 10

M1 - 1450058

ER -

Applications of a nonlinear evolution equation II: The EMC effect

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