پژوهشگاه دانش‌های بنیادی

“مریم سلیمانی نیا”

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+98 21 22809150

دورنگار:
+98 21 22809148

پست الکترونیکی:

سمت در پژوهشگاه

پژوهشگر مقیم، پژوهشکده ذرات و شتابگر
(1403 تا اکنون )

سمت‌های پیشین در پژوهشگاه

پسا دکتری، پژوهشکده ذرات و شتابگر
(1398 تا 1403)

پژوهشگر مقیم، پژوهشکده ذرات و شتابگر
(1396 تا 1398)

پژوهشگر دانشجو خارج از پژوهشگاه، پژوهشکده ذرات و شتابگر
(1390 تا 1392)

علایق پژوهشی

Phenomenological study of high energy physics

فعالیت‌های پژوهشی

Quantum chromodynamics (QCD) is the generally accepted fundamental theory of the strong interaction. According to the asymptotic freedom many high energy scattering processes can be calculated by using perturbative theory. Theoretically such processes are in the form of factorization theorems and separate the perturbative part of the cross section from the non-perturbative part. In finding any exotic physics signatures beyond the standard model and any new hadronic systems in high energy hadron reactions, for example, at RHIC (Relativistic Heavy Ion Collider) and LHC (Large Hadron Collider), it is necessary to have accurate QCD predictions for cross sections. The perturbative QCD is now understood in the next-to leading order (NLO) or next-to-next-to-leading order (NNLO) levels for differnt processes. Therefore, the crucial part is to understand nonperturbative aspects, namely, parton distribution functions (PDFs) and fragmentation functions (FFs). Fragmentation functions are used in high-energy reaction processes with hadron production. They include hadron-production processes in electron-positron annihilation, electron, muon, and neutrino scattering from proton or nucleus, proton-proton collisions, and heavy-ion collisions. Such reactions are becoming increasingly important in hadron physics for investigating the origin of the proton spin and quark-hadron matters in heavy-ion reactions.

پروژهٔ پژوهشی فعلی در پژوهشگاه

High Energy Physics

مقالات

1. M. Soleymaninia, H. Hashamipour, M. Salajegheh, H. Khanpour, H. Spiesberger and Ulf-G. Meissner
Determination of $K^0_S$ Fragmentation Functions including {\tt BESIII} Measurements and using Neural Networks
(Submitted) [abstract]
arXive.org link: 2404.07334 [ abs, src, ps, others], cited by
Code: IPM/P.A-802

2. M. Salajegheh, H. Khanpour, Ulf-G. Meissner, H. Hashamipour and M. Soleymaninia
Determination of diffractive PDFs from a global QCD analysis of inclusive diffractive DIS and dijet cross-section measurements at HERA
Phys. Rev. D 107 (2023), [abstract]
Code: IPM/P.A-776

3. M. Soleymaninia, H. Hashamipour, H. Khanpour, S. Shoeibi and A. Mohamaditabar
Nuclear corrections on the charged hadron fragmentation functions in a Neural Network global QCD analysis
(Submitted) [abstract]
arXive.org link: 2305.02664v1 [ abs, src, ps, others], cited by
Code: IPM/P.A-775

4. M. Salajegheh, H. Khanpour, Ulf-G . Meissner, H. Hashamipour and M. Soleymaninia
Global QCD analysis of diffractive parton distribution function considering higher twist corrections within the xFitter framework
Phys. Rev. D 106 (2022), [abstract]
arXive.org link: 2206.13788 [ abs, src, ps, others], cited by
Code: IPM/P.A-753

5. M. Soleymaninia, H. Hashamipour, H. Khanpour and H. Spiesberger
Fragmentation Functions for $\Xi ^-/\bar{\Xi}^+$ Using Neural Networks
Nucl. Phys. A 1029 (2022), [abstract]
arXive.org link: 2202.05586 [ abs, src, ps, others], cited by
Code: IPM/P.A-752

6. M. Soleymaninia, H. Hashamipour and H. Khanpour
Neural network QCD analysis of charged hadron fragmentation functions in the presence of SIDIS data
Phys. Rev. D 105 (2022), [abstract]
arXive.org link: 2202.10779 [ abs, src, ps, others], cited by
Code: IPM/P.A-742

7. H. Abdolmaleki, M. Soleymaninia, H. Khanpour, S. Amoroso, F. Giuli, A. Glazov, A. Luszczak, F. Olness and O. Zenaiev
QCD analysis of pion fragmentation functions in the xFitter framework
Phys. Rev. D 104 (2021), [abstract]
Code: IPM/P.A-718

8. H. Khanpour, M. Soleymaninia, S. Atashbar Tehrani, H. Spiesberger and V. Guzey
Nuclear parton distribution functions with uncertainties in a general mass variable flavor number scheme
Phys. Rev. D 104 (2021), [abstract]
arXive.org link: 2010.00555 [ abs, src, ps, others], cited by
Code: IPM/P.A-716

9. M. Soleymaninia, M. Goharipour, H. Khanpour and H. Spiesberger
Simultaneous extraction of fragmentation functions of light charged hadrons with mass corrections
Phys. Rev. D 103 (2021), [abstract]
Code: IPM/P.A-678

10. M. Soleymaninia, H. Abdolmaleki and H. Khanpour
First NNLO fragmentation functions of K_S^O and Λ/―Λ and their uncertainties in the presence of hadron mass corrections
Phys. Rev. D 102 (2020), [abstract]
Code: IPM/P.A-662

11. M. Delpasand, M. Moosavi Nejad and M. Soleymaninia
Λ ⁺_c fragmentation functions from pQCD approach and the Suzuki model
Phys. Rev. D 101 (2020), [abstract]
Code: IPM/P.A-631

12. A. Mohamaditabar, F. Taghavi-Shahri, H. Khanpour and M. Soleymaninia
Determination of contributions from residual light charged hadrons to inclusive charged hadrons from e(+)e(-) annihilation data
Eur. Phys. J. A 55 (2019), [abstract]
Code: IPM/P.A-645

13. M. Salajegheh, S. M. Moosavi Nejad, M. Soleymaninia, H. Khanpour and S. Atashbar Tehrani
NNLO charmed-meson fragmentation functions and theiruncertainties in the presence of meson mass corrections
Eur. Phys. J. C 79 (2019), [abstract]
arXive.org link: arXiv:1904.09832 [hep-ph] [ abs, src, ps, others], cited by
Code: IPM/P.A-604

14. M. Soleymaninia and H. Khanpour
Transverse momentum dependent of charged pion, kaon and proton fragmentation functions from e⁺e⁻ annihilation process
Phys. Rev. D 100 (2019), [abstract]
arXive.org link: 1907.12294 [hep-ph] [ abs, src, ps, others], cited by
Code: IPM/P.A-597

15. M. Salajegheh, S. M. Moosavi Nejad, M. Soleymaninia, H. Khanpour and S. Atashbar Tehrani
NNLO charmed-meson fragmentation functions and their uncertainties in the presence of meson mass corrections
Eur. Phys. J. C 79 (2019), [abstract]
arXive.org link: 1904.09832 [hep-ph] [ abs, src, ps, others], cited by
Code: IPM/P.A-595

16. M. Salajegheh, S. M. Moosavi Nejad, H. Khanpour, . A. Kniehl and M. Soleymaninia
B-hadron fragmentation functions at next-to-next-to-leading order from global analysis of e⁺e⁻ annihilation data
Phys. Rev. D 99 (2019), [abstract]
arXive.org link: arXiv:1904.08718 [hep-ph] [ abs, src, ps, others], cited by
Code: IPM/P.A-549

17. M. Soleymaninia , M. Goharipour and H. Khanpour
Impact of unidentified light charged hadron data on the determination of pion fragmentation functions
Phys. Rev. D 99 (2019), [abstract]
arXive.org link: 1901.01120 [hep-ph] [ abs, src, ps, others], cited by
Code: IPM/P.A-534

18. A. Mohamaditabar, F. Taghavi shahri, H. Khanpour and M. Soleymaninia
Determination of residual light charged hadrons contribution to the inclusive charged hadrons from e+e- annihilation data
Eur. Phys. J. A 55 (2019), [abstract]
Code: IPM/P.A-510

19. M. Soleymaninia, M. Goharipour and H. Khanpour
First QCD analysis of charged hadron fragmentation functions and their uncertainties at next-to-next-to-leading order
Phys. Rev. D 98 (2018), [abstract]
arXive.org link: arXiv:1805.04847 [hep-ph] [ abs, src, ps, others], cited by
Code: IPM/P.A-502

20. M. Soleymaninia, H. Khanpour and S. M. Moosavi Nejad
First determination of D^*+-meson fragmentation functions and their uncertainties at next-to-next-to-leading order
Phys. Rev. D 97 (2018), [abstract]
Code: IPM/P.A-488

21. S.M. Moosavi Nejad, M. Soleymaninia and A. N. Khorramian
Global analysis of fragmentation functions and their application to polarized top quark decays considering new BABAR and Belle experimental data
Canadian J. Physics 10.1139 (2016), [abstract]
Code: IPM/P.A-453

22. S.M. Moosavi Nejad, M. Soleymaninia and A. Maktoubian
Proton fragmentation functions considering finite-mass corrections
Eur. Phys. J. A 52 (2016), [abstract]
Code: IPM/P.A-445

23. F. Arbabifar, A.N. Khorramian and M. Soleymaninia
The Effect of Polarized DIS Hadronization Process on the Determination of Polarized Parton Distributions
( In: Acta Physica Polonica B, Vol.7, 585 (2014) )
[abstract]
Code: IPM/P.A-385

24. M. Soleymaninia, A.N. Khorramian, M. Moosavi Nejad and F. Arbabifar
The Role of Hadronization Processes in Determination of Fragmentation Functions
( In: Acta Physica Polonica B, Vol.7, 573 (2014))
[abstract]
Code: IPM/P.A-350

25. F. Arbabifar, A.N. Khorramian and M. Soleymaninia
QCD analysis of polarized DIS and the SIDIS asymmetry world data and light sea-quark decomposition
Phys. Rev. D 89 (2014), [abstract]
Code: IPM/P.A-335

26. F. Arbabifar, A.N. Khorramian and M. Soleymaninia
QCD analysis of polarized DIS and the SIDIS asymmetry world data and light sea-quark decomposition
( In: XV Advanced Research Workshop on High Energy Spin Physics (DSPIN, Dubna, October 8-12, 2013))
[abstract]
Code: IPM/P.A-334

27. M. Soleymaninia, A.N. Khorramian, S. M. Moosavinejad and F. Arbabifar
QCD Analysis of Fragmentation Functions Considering Double Spin Asymmetry of SIDIS Processes
Physics of Particles and Nuclei 45 (2014), 46-48 [abstract]
Code: IPM/P.A-331

28. M. Soleymaninia, A.N. Khorramian, S. M. Moosavinejad and F. Arbabifar
Determination of pion and kaon fragmentation functions including spin asymmetries data in a global analysis
Phys. Rev. D 88,054019 (2013), 1-19 [abstract]
Code: IPM/P.A-299

29. M. Soleymaninia, A. N. Khorramian and M. Moosavi Nejad
Extraction of Pion Non-Perturbative Fragmentation Functions In ZM-VFNS
AIP CONF PROC (2012), 67-70 [abstract]
Code: IPM/P.A-287

30. M. Soleymaninia, A.N. Khorramian and M. Moosavi nejad
Pion fragmentation functions from e+e- production
Journal of Physics, (JPCS) (2012), [abstract]
Code: IPM/P.A-205

31. M. Soleimaninia and A.N. Khorramian
Non-Singlet Part Of The Longitudinal Structure Function FL Up To O(a3S)
Int. J. Mod. Phys. A 26 (2011), 686-687 [abstract]
Code: IPM/P.A-139

32. M. Soleymaninia, A.N. Khorramian and S. Atashbar Tehrani
A phenomenological analysis of the longitudinal proton structure function FL
( In: The Conference in Honour of Murray Gell-Mann's 80th Birthday,2010)
[abstract]
Code: IPM/P.A-111

33. A.N. Khorramian, S. Atashbar Tehrani, M. Soleymaninia and S. Batebi
FL Structure Function and Heavy Quark Contributions
Hyperfine Interactions 194 (2009), 341-345 [abstract]
Code: IPM/P.A-042

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“مریم سلیمانی نیا”

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علایق پژوهشی

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خدمات الکترونیکی

سمت در پژوهشگاه
پژوهشگر مقیم، پژوهشکده ذرات و شتابگر (1403 تا اکنون )
سمت‌های پیشین در پژوهشگاه
پسا دکتری، پژوهشکده ذرات و شتابگر (1398 تا 1403) پژوهشگر مقیم، پژوهشکده ذرات و شتابگر (1396 تا 1398) پژوهشگر دانشجو خارج از پژوهشگاه، پژوهشکده ذرات و شتابگر (1390 تا 1392)
علایق پژوهشی
Phenomenological study of high energy physics
فعالیت‌های پژوهشی
Quantum chromodynamics (QCD) is the generally accepted fundamental theory of the strong interaction. According to the asymptotic freedom many high energy scattering processes can be calculated by using perturbative theory. Theoretically such processes are in the form of factorization theorems and separate the perturbative part of the cross section from the non-perturbative part. In finding any exotic physics signatures beyond the standard model and any new hadronic systems in high energy hadron reactions, for example, at RHIC (Relativistic Heavy Ion Collider) and LHC (Large Hadron Collider), it is necessary to have accurate QCD predictions for cross sections. The perturbative QCD is now understood in the next-to leading order (NLO) or next-to-next-to-leading order (NNLO) levels for differnt processes. Therefore, the crucial part is to understand nonperturbative aspects, namely, parton distribution functions (PDFs) and fragmentation functions (FFs). Fragmentation functions are used in high-energy reaction processes with hadron production. They include hadron-production processes in electron-positron annihilation, electron, muon, and neutrino scattering from proton or nucleus, proton-proton collisions, and heavy-ion collisions. Such reactions are becoming increasingly important in hadron physics for investigating the origin of the proton spin and quark-hadron matters in heavy-ion reactions.
پروژهٔ پژوهشی فعلی در پژوهشگاه
High Energy Physics
مقالات


1.	M. Soleymaninia, H. Hashamipour, M. Salajegheh, H. Khanpour, H. Spiesberger and Ulf-G. Meissner Determination of $K^0_S$ Fragmentation Functions including {\tt BESIII} Measurements and using Neural Networks (Submitted) [abstract] arXive.org link: 2404.07334 [ abs, src, ps, others], cited by Code: IPM/P.A-802


2.	M. Salajegheh, H. Khanpour, Ulf-G. Meissner, H. Hashamipour and M. Soleymaninia Determination of diffractive PDFs from a global QCD analysis of inclusive diffractive DIS and dijet cross-section measurements at HERA Phys. Rev. D 107 (2023), [abstract] Code: IPM/P.A-776


3.	M. Soleymaninia, H. Hashamipour, H. Khanpour, S. Shoeibi and A. Mohamaditabar Nuclear corrections on the charged hadron fragmentation functions in a Neural Network global QCD analysis (Submitted) [abstract] arXive.org link: 2305.02664v1 [ abs, src, ps, others], cited by Code: IPM/P.A-775


4.	M. Salajegheh, H. Khanpour, Ulf-G . Meissner, H. Hashamipour and M. Soleymaninia Global QCD analysis of diffractive parton distribution function considering higher twist corrections within the xFitter framework Phys. Rev. D 106 (2022), [abstract] arXive.org link: 2206.13788 [ abs, src, ps, others], cited by Code: IPM/P.A-753


6.	M. Soleymaninia, H. Hashamipour and H. Khanpour Neural network QCD analysis of charged hadron fragmentation functions in the presence of SIDIS data Phys. Rev. D 105 (2022), [abstract] arXive.org link: 2202.10779 [ abs, src, ps, others], cited by Code: IPM/P.A-742


7.	H. Abdolmaleki, M. Soleymaninia, H. Khanpour, S. Amoroso, F. Giuli, A. Glazov, A. Luszczak, F. Olness and O. Zenaiev QCD analysis of pion fragmentation functions in the xFitter framework Phys. Rev. D 104 (2021), [abstract] Code: IPM/P.A-718


8.	H. Khanpour, M. Soleymaninia, S. Atashbar Tehrani, H. Spiesberger and V. Guzey Nuclear parton distribution functions with uncertainties in a general mass variable flavor number scheme Phys. Rev. D 104 (2021), [abstract] arXive.org link: 2010.00555 [ abs, src, ps, others], cited by Code: IPM/P.A-716


9.	M. Soleymaninia, M. Goharipour, H. Khanpour and H. Spiesberger Simultaneous extraction of fragmentation functions of light charged hadrons with mass corrections Phys. Rev. D 103 (2021), [abstract] Code: IPM/P.A-678


10.	M. Soleymaninia, H. Abdolmaleki and H. Khanpour First NNLO fragmentation functions of K_S^O and Λ/―Λ and their uncertainties in the presence of hadron mass corrections Phys. Rev. D 102 (2020), [abstract] Code: IPM/P.A-662


11.	M. Delpasand, M. Moosavi Nejad and M. Soleymaninia Λ ⁺_c fragmentation functions from pQCD approach and the Suzuki model Phys. Rev. D 101 (2020), [abstract] Code: IPM/P.A-631


12.	A. Mohamaditabar, F. Taghavi-Shahri, H. Khanpour and M. Soleymaninia Determination of contributions from residual light charged hadrons to inclusive charged hadrons from e(+)e(-) annihilation data Eur. Phys. J. A 55 (2019), [abstract] Code: IPM/P.A-645


13.	M. Salajegheh, S. M. Moosavi Nejad, M. Soleymaninia, H. Khanpour and S. Atashbar Tehrani NNLO charmed-meson fragmentation functions and theiruncertainties in the presence of meson mass corrections Eur. Phys. J. C 79 (2019), [abstract] arXive.org link: arXiv:1904.09832 [hep-ph] [ abs, src, ps, others], cited by Code: IPM/P.A-604


14.	M. Soleymaninia and H. Khanpour Transverse momentum dependent of charged pion, kaon and proton fragmentation functions from e⁺e⁻ annihilation process Phys. Rev. D 100 (2019), [abstract] arXive.org link: 1907.12294 [hep-ph] [ abs, src, ps, others], cited by Code: IPM/P.A-597


16.	M. Salajegheh, S. M. Moosavi Nejad, H. Khanpour, . A. Kniehl and M. Soleymaninia B-hadron fragmentation functions at next-to-next-to-leading order from global analysis of e⁺e⁻ annihilation data Phys. Rev. D 99 (2019), [abstract] arXive.org link: arXiv:1904.08718 [hep-ph] [ abs, src, ps, others], cited by Code: IPM/P.A-549


17.	M. Soleymaninia , M. Goharipour and H. Khanpour Impact of unidentified light charged hadron data on the determination of pion fragmentation functions Phys. Rev. D 99 (2019), [abstract] arXive.org link: 1901.01120 [hep-ph] [ abs, src, ps, others], cited by Code: IPM/P.A-534


18.	A. Mohamaditabar, F. Taghavi shahri, H. Khanpour and M. Soleymaninia Determination of residual light charged hadrons contribution to the inclusive charged hadrons from e+e- annihilation data Eur. Phys. J. A 55 (2019), [abstract] Code: IPM/P.A-510


19.	M. Soleymaninia, M. Goharipour and H. Khanpour First QCD analysis of charged hadron fragmentation functions and their uncertainties at next-to-next-to-leading order Phys. Rev. D 98 (2018), [abstract] arXive.org link: arXiv:1805.04847 [hep-ph] [ abs, src, ps, others], cited by Code: IPM/P.A-502


20.	M. Soleymaninia, H. Khanpour and S. M. Moosavi Nejad First determination of D^+-meson fragmentation functions and their uncertainties at next-to-next-to-leading order* Phys. Rev. D 97 (2018), [abstract] Code: IPM/P.A-488


21.	S.M. Moosavi Nejad, M. Soleymaninia and A. N. Khorramian Global analysis of fragmentation functions and their application to polarized top quark decays considering new BABAR* and Belle experimental data* Canadian J. Physics 10.1139 (2016), [abstract] Code: IPM/P.A-453


23.	F. Arbabifar, A.N. Khorramian and M. Soleymaninia The Effect of Polarized DIS Hadronization Process on the Determination of Polarized Parton Distributions ( In: Acta Physica Polonica B, Vol.7, 585 (2014) ) [abstract] Code: IPM/P.A-385


24.	M. Soleymaninia, A.N. Khorramian, M. Moosavi Nejad and F. Arbabifar The Role of Hadronization Processes in Determination of Fragmentation Functions ( In: Acta Physica Polonica B, Vol.7, 573 (2014)) [abstract] Code: IPM/P.A-350


27.	M. Soleymaninia, A.N. Khorramian, S. M. Moosavinejad and F. Arbabifar QCD Analysis of Fragmentation Functions Considering Double Spin Asymmetry of SIDIS Processes Physics of Particles and Nuclei 45 (2014), 46-48 [abstract] Code: IPM/P.A-331


29.	M. Soleymaninia, A. N. Khorramian and M. Moosavi Nejad Extraction of Pion Non-Perturbative Fragmentation Functions In ZM-VFNS AIP CONF PROC (2012), 67-70 [abstract] Code: IPM/P.A-287


30.	M. Soleymaninia, A.N. Khorramian and M. Moosavi nejad Pion fragmentation functions from e+e- production Journal of Physics, (JPCS) (2012), [abstract] Code: IPM/P.A-205


31.	M. Soleimaninia and A.N. Khorramian Non-Singlet Part Of The Longitudinal Structure Function FL Up To O(a3S) Int. J. Mod. Phys. A 26 (2011), 686-687 [abstract] Code: IPM/P.A-139


32.	M. Soleymaninia, A.N. Khorramian and S. Atashbar Tehrani A phenomenological analysis of the longitudinal proton structure function FL ( In: The Conference in Honour of Murray Gell-Mann's 80th Birthday,2010) [abstract] Code: IPM/P.A-111


33.	A.N. Khorramian, S. Atashbar Tehrani, M. Soleymaninia and S. Batebi FL Structure Function and Heavy Quark Contributions Hyperfine Interactions 194 (2009), 341-345 [abstract] Code: IPM/P.A-042