Dr.G.R.Boroun
Associated Professor of Physics
Particle and High Energy Physics
(Phenomenological) (HEP-PH)


Address: School of Science, Razi University, Tagh Bostan, Kermanshah, Iran
Tel: +98(831)4274556
Fax: +98(831)4274556
Emails: (☻=AT)
boroun☻ razi.ac.ir
grboroun☻ gmail.com
Homepage: http://www.razi.ac.ir/Boroun


Details:
Surname: Boroun
First name: G.R.
Date and place of birth: 23/09/1972, Iran
RANK: Assistant professor (2003 – 2010)
           : Associated Professor (2010 – till date)


Education:
BS: Physics, Razi University Iran, 1994
MSc: M.Sc. Physics, Sh. Chamran University Iran, 1998
M.Sc. Thesis Title: The Aharanof- Bohm effect in Bound state.
PhD:
Physics, Shiraz University Iran, 2003
Dissertation: " Calculation of the Proton Structure Functions in Neutral Current Deep Inelastic Scattering"


Professional Experiences:
Associate Professor, Physics Department, Razi University, Kermanshah, Iran, 2010.
Assistant Professor, Physics Department, Razi University, Kermanshah, Iran, 2003-2010.


Job descriptions:
I am an academic member of Razi university of Kermanshah in Iran. I have graduated 15 MSC students. At the moment I am supervisor of seven PhD student and five MSC students. Also I am a Member of Iranian Physical society.


Research Areas:
Deep Inelastic Scattering
-Parton Distribution Functions(Singlet and nonsinglet )
-Proton Structure
-Photon Structure Functions
-Polarized and Unpolarized Proton Structure Functions
-Fragmentation Functions
-Nuclear Fragmentation
-Charm Structure Functions
-Quark-gluon plasma phase transition to Hadron matter
- Analysis in Hadron Elastic Scattering.
-Regge-Pole Model
-Low-x Physics
-Mathematical Calculations of the Parton distribution Functions
-Mathematical Methods in Valon Model
-Particle Exchange Theory
-Form Factor calculation in nucleons
-MIT Bag Model
-Color Dipole Model
-Pomeron Physics
-Fragmentation function


Current Research Activities:
Parton distribution functions calculation at low-x
Pomeron physics at low-x
Proton structure function
Gluon distribution function
Longitudinal structure function
Charm structure function
Quark-gluon plasma phase transition to hadron matter
Nucleon structure function calculations in e-p deep inelastic scattering.
Nucleon form factor determination in e-p elastic scattering.
Form Factor Determination in Nucleons.
Deep inelastic cross section and its derivatives
Saturation and non- linear gluon evolution
Regge behavior
Low-x Physics


List of Publications:
1. Solving Schrodinger equation for time dependence Aharanof-Bohm effect, Sh.Chamran University Journal of Science, No.6,P.1,Summer 2000.

2. Extraction of structure function F_2 at low-x from the cross section derivative, Phys. Lett. B528, 239, 2002.


3. Calculation of the gluon distribution function using alternative method for the proton structure function, Comm. Theor. Phys. 40, 551, 2003.

4. Quasi-elastic electron-deuteron scattering and calculation of neutron electromagnetic form factor at Q^2=1.75 to 4.00 (GeV/c)^2, Comm. Theor. Phys. 39, 685, 2003.

5. Charge dependency of strong nuclear force via phase shift analysis of nucleon-nucleon potential, Comm. Theor. Phys. 41, 279, 2004.

6. Extraction of structure function and gluon distribution function at low-x from cross section derivative by Regge behavior, Commun. Theor. Phys. 43, 283, 2005.

7. Calculation of the gluon distribution functions in leading order by Regge behavior at low-x, Commun. Theor. Phys. 44, 891, 2005.

8. A solution of the DGLAP equation for gluon distribution as a function of F_2 and dF_2/dlnQ^2 at low-x, the next to leading order analysis, Chin. Phys. Lett. 23, No. 2, 324, 2006.

9. Calculation of the exponent lambda based on the behavior of steeply rising gluon distribution function at low-x, Acta. Phys. Slovaca, 56, No. 4, 463, 2006.

10. Calculation of longitudinal structure function by Regge-like behavior of gluon distribution function at low-x, Chin. Phys. Lett. 24, No. 5, 1187, 2007.

11. The approximation method for calculation the exponents of the gluon distribution-λg and the structure function-λS at low x in the next to leading order analysis, Phys. Atom. Nucl. 71, No. 6, 1077 (2008) [arXiv:hep-ph/1402.0768 ].

12. Solutions of independent DGLAP evolution equations for the gluon distribution and singlet structure functions in the next-to-leading order analysis at low x, JETP,106, No. 4, 700 (2008) [arXiv:hep-ph/1402.0174 ].

13. Determination of the proton bag radius based on MIT bag model, International Journal of Theoretical Physics, 12, No. 4, 113 (2008).

14. Analytical solutions for the reduced cross section and its derivatives at low x based on gluon and structure function exponents, Lithuanian Journal of Physics, 48, No. 2, 121 (2008).

15. Hard-Pomeron behavior of the longitudinal structure function F_L in the next-to-leading-order at low x, International Journal of Modern Physics E, 18, No. 1,1 (2009) [arXiv:hep-ph/1402.0762 ].

16. Shadowing correction to the gluon distribution behavior at small x, Eur. Phys. J. A42, 251 (2009)[arXiv:hep-ph/1402.0864].

17. Nonlinear correction to the Longitudinal structure function at small x, Eur.Phys.J.43, 335(2010) [arXiv:hep-ph/ 1402.1186 ].

18. Neutron bag radius from the electric and magnetic neutron form factors at Q^2=1.75 - 4 (GeV/c)_2, International Journal of Theoretical Physics, Vol. 14, Issue #1, 1 (2009).

19. Variational and exact solution of the wave function at origin (WFO) for heavy quarkonium by a global potential, Physica Scripta. 80, 065003 (2009).

20. Analysis of the logarithmic slope of F2 from the Regge gluon density behavior at small x, JETP, 138, No. 3(9), 1 (2010) [arXiv:hep-ph/1402.0178 ].

21. Analytical approach for the approximate solution of the longitudinal structure function with respect to the GLR-MQ equation at small x, Phys. Lett. B692, 247 (2010) [arXiv:hep-ph/1402.0752 ].

22. Analytic approach to the approximate solution of the independent DGLAP evolution equations with respect to the hard-Pomeron behavior, JETP, 112, No. 3, 381 (2011)[arXiv:hep-ph/1402.0789 ].

23. Analytical solution of the longitudinal structure function FL in the leading and next-to-leading-order analysis at low x with respect to Laguerre polynomials method, Nucl. Phys. A857, 42 (2011) [arXiv:hep-ph/1402.0173 ].

24. NLO corrections to the hard Pomeron behavior of the charm structure functions F_c^k (k = 2, L) at low-x, Nucl. Phys. B857, 143 (2012) [arXiv:hep-ph/1402.0166 ].

25. The ratio of the charm structure functions at low-x in DIS with respect to the expansion method, JETP142, 3(9), 1 (2012) [arXiv:hep-ph/1402.0167 ].

26. An analysis of the proton structure function from the gluon distribution function, Phys. Scr. 86, 015101 (2012).

27. The predictions of the charm structure function exponents behavior at low x in deep inelastic scattering, Eur. Phys. Lett., 100, 41001 (2012) [arXiv:hep-ph/1402.0165 ].

28. Analysis of the proton longitudinal structure function from the gluon distribution function, Eur. Phys. J. C72, 2221 (2012) [arXiv:hep-ph/1401.7804 ].

29. Longitudinal structure function F_L from charm structure function F_2^C, Commun.Theor.Phys.59, 462 (2013) [arXiv:hep-ph/1402.0163 ].

30. Decoupling of the DGLAP evolution equations at next-to-next-to-leading order (NNLO) at low-x, Eur. Phys. J.C73, 2412 (2013) [arXiv:hep-ph/1402.0164 ].

31. Laguerre polynomials method in valon model, Phys.Scripta, 88, 035102 (2013) [arXiv:hep-ph/1402.0162 ].

32. An approximate approach to the nonlinear DGLAP evaluation equation, Eur. Phys. J. Plus 128, 119(2013) [arXiv:hep-ph/1402.0678 ].

33. Fragmentation of heavy quarks using wave function at the origin, Universal Journal of physics and application 1(2), 59(2013).

34. An Approximation Method for Three Quark Systems in the Hyper-Spherical Approach, International Journal of Physical Sciences and Engineering Vol:7 No:4, 874 (2013).

35. Proton and Neutron Magnetic Moments Based On Bag Models, International Journal of Physical Sciences and Engineering Vol:7 No:5, 855(2013).

36. Shadowing corrections to the derivative of the reduced cross section at small x, PRAMANA _ journal of physics Vol. 82, No. 6, pp. 1031–1038 (2014).

37. Spin acceleration on spin current in 2DEG, IJTPNO, Vol.17, No.2, 75(2014).

38. Evolution of the Longitudinal Structure Function at Small-x, Eur. Phys. J. Plus 19, 129(2014) [arXiv:hep-ph/1402.0680 ].

39. Dynamical behavior connection of the gluon distribution and the proton structure function at small x, Eur. Phys. J. A50, 69 (2014) [arXiv:hep-ph/ 1404.5008].

40. Spin force on pseudo spin current in grapheme, Universal Journal of physics and application 2(5), 245-250(2014).

41. Geometrical scaling in charm structure function ratios, Nuclear Physics A 929, 119–128 (2014) [arXiv:hep-ph/1408.2204] .

42. The ratio of the beauty structure functions at low-x, Nucl.Phys.B 884, 684 (2014) [arXiv:hep-ph/1406.0061] .

43. Laplace method for evolution of the fragmentation functions of Bc mesons. will be appear in NPA(2016).

44. The behavior of the heavy-quarks structure functions at small-x, Int.J.Mod.Phys. E24 (2015) 08, 1550063[arXiv:1507.06770].

45. NLO corrections to the valon model,
PRAMANA- journal of  physics , Vol. 86, No. 1, January 2016,pp. 77–86.

46. An approximation approach to the evolution of the fragmentation function, IJTP 54(2015)3831.

47. A Phenomenological Solution to the Longitudinal Structure Function Dynamical Behavior at Small-x,
International Journal of Modern Physics A, Vol. 29 (2014) 1450189 [arXiv:hep-ph/1412.1552].

48. Top Structure function at the LHeC, Physics Letters B741 (2015)197 [arXiv:hep-ph/
1411.6492 ].

49. Geometrical scaling behavior of the top structure functions ratio at the LHeC ,  Physics Letters B744(2015)142 [arXiv:hep-ph/ 1503.01590].

50. The non-singlet structure function evolution by Laplace method, Physics of Atomic Nuclei, 2015, Vol. 78, No. 9(2015) 944.

51. Analysis of the Longitudinal Structure Function 𝐹L from the Non-linear Regge Gluon Density Behavior at Low-𝑥, CHIN. PHYS. LETT. Vol. 32, No. 11 (2015) 111101.

52. Decoupling of the DGLAP evolution equations by Laplace method,    EPJP130(2015)214.

53. Laplace method for evolution of the fragmentation functions of Bc mesons. Nuclear Physics A 953 (2016) 21–31.

54.
NLO corrections to the valon model, PRAMANA- journal of physics , Vol. 86, No. 1, January 2016,pp. 77–86.

55. The non-singlet spin-dependent structure function evolution by Laplace and characteristics methodsPhysics of Atomic Nuclei, 2016, Vol. 79, No. 2, pp. 236–242.

56.
Ground state energy shift of charmonium on noncommutative space, Journal of Research on Many-body Systems, Volume 6, Number 12, Winter 2017, Page 11.

57. Top reduced cross section behavior at the LHeC kinematic range, Chin.Phys. C41 (2017) no.1, 013104.

58. Oً(θ) Feynman rules for quadrilinear gauge boson couplings in the
noncommutative standard model, PHYSICAL REVIEW D 95, 035034 (2017).

59.
The Exponent of the Non Singlet Structure Function at Leading Order up to Next-to-leading Order Analysis,  Int. J. Theor .Phys. 2017. Accepted.

60.
Solution of DGLAP evolution equation for gluon fragmentation in LO and NLO,  Iranian Journal of Physics Research, 2017.

Books Written:
1. "Introduction to elementary particles", 2009, Razi Univ. Press., Iran.


Presentation in Conferences:
1. Iranian Annual Physics Conference, 27-30 August 2001, Sabzevar, P.34.

2. Iranian Annual Physics Conference, 25-28 August 2003, Tabriz, P.19.

3. Lecture in the first QCD workshop (IPM), 4-5 Feb. 2004.

4. XIII International Conference "Selected Problems of Modern Theoretical Physics", 23-27 June, 2008, Dubna, Russia.

5. Behavior of the longitudinal structure function in NLO analysis at low x, EPS-HEP 2009, Krakow, Poland,16-22 July (2009).

6. Iranian Annual Physics Conference, 15-18 August 2009, Esfahan, P.1083.

7. 17th Physics Spring Conference, 5-6 May 2010, Tehran (IPM), P.130.

8. Two Approaches to the Ratio of the Charm Structure Functions, The XIth International Conference on Heavy Quarks and Leptons, June 11-15, 2012 Prague, Czech Republic.

9. 20th Physics Spring Conference, 22-23 May 2013, Tehran (IPM).

10. 21th Physics Spring Conference, 21-22 May 2014, Tehran (IPM).


Visiting:
1) Particle Theory Group, Department of Physics, University of Zurich(UZH), Sep.2014. 

Invited:
1)
CERN 24-26 Jun 2015.  LHeC workshop in the Physics and Detector session that take place on the 25 & 26th of June at Chavannes-de-Bogis, Switzerland.

2) 6th Particles and fields Conference, 20-21 Jan. 2016, Esfahan university and technology.

Courses Taught:
General Physics (Tex: Halliday & Resnick)

Modern Phys. (Beiser, Weidner & Sells)

Elem. particle Physics (Frauenfelder & Hendely)

Elem. Particle physics(David Griffiths)

Elem. Particle physics(Halzen and Martin)

Quantum Mechanics (Gasiorowicz)

Classical Mechanics (Fowles)

Quantum Field Theory (Huang & Mandl and Shaw )

Relativistic Quantum Mechanics and Field Theory(Gross)

Quantum Cheromodynamics (Greiner)

The structure of the proton (Roberts)

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