Condensed Matter Physics, University of New South Wales, Sydney, Australia (1994)
كارشناسي ارشد:
Physics, Tehran University, Tehran, Iran (1988 )
كارشناسي :
Physics, National University of Iran, Tehran, Iran (1986)
زمینه های تدریس
I : Undergraduate Level
1. Basic Physics I (Fundamentals of Physics, D. Halliday et. al.)
2. Basic Physics II (Fundamentals of Physics, D. Halliday et. al.)
3. Basic Physics III (Fundamentals of Physics, D. Halliday et. al.)
4. Mathematical Physics I (Mathematical Methods for Physicists, G. Arfken et. al.)
5. Mathematical Physics II (Mathematical Methods for Physicists, G. Arfken et. al.)
6. Analytical Mechanics I (Mechanics, K. Symon)
7. Analytical Mechanics II (Mechanics, K. Symon)
8. Thermodynamics (Heat and Thermodynamics, M. Zemansky)
9. Modern Physics (Fundamentals of Modern Physics, R. Eisberg)
10. Electronics I (Integrated Electronics, J. Millman and C. Halkias)
11. Electronics II (Integrated Electronics, J. Millman and C. Halkias)
12. Vacuum Technology (Modern Vacuum Practice, N. Harris)
13. Waves (Waves, F. S. Crawford)
14. Crystallography (Introduction to Crystallography, C. Hammond)
15. Solid State Physics (Introduction to Solid State Physics, C. Kittel)
16. Physics of Semiconductors (Physics of Semiconductors Devices, S. M. Sze)
17. English for Physics Students (Different Articles)
18. Electromagnetic I (Foundations of Electromagnetic Theory, J. R. Reitz, F. J. Milford, and R. W. Christy)
19. Electromagnetic II (Foundations of Electromagnetic Theory, J. R. Reitz, F. J. Milford, and R. W. Christy)
20. Workshop
21. Quantum Mechanics I (Quantum Physics, S. Gasiorowicz)
22. Quantum Mechanics II (Quantum Physics, S. Gasiorowicz)
II : Graduate Level
a) MSc Level
1. Advanced Solid State Physics I (Solid State Physics, N. Ashcraft and N. Mermin)
2. Advanced Solid State Physics II (Solid State Physics, N. Ashcraft and N. Mermin)
3. Classical Mechanics (Classical Mechanics, H. Goldstein)
4. Advanced Physics Lab
5. Special Subjects
6. Electrodaynamics I (Classical Electrodynamics, J. D. Jackson)
7. Advanced Quantum Mechanics I (Modern Quantum Mechanics, J. J. Sakurai)
8. Advanced Quantum Mechanics II (Modern Quantum Mechanics, J. J. Sakurai)
9. Theory and Technology of Optical Devices Manufacturing (VLSI Technology, S. M. Sze)
b) PhD Level
1. Condensed Matter Physics I (A Quantum Approach to Condensed Matter Physics, P. L. Taylor and O. Heinone)
2. Special Topics in Physics
3. Self Study (Different Articles)
4. Preparation and Characterization of Nanopatricles and Nanostructures (Nanoparticles and Nanostructured Films, J. H. Fendler)
5. Nanoparticles and Nanostructures (Nanostructurtes: Theory and Modeling, C. Delerue and M. Lannoo)
6. Wave Scattering from Rough Surfaces (Theory of Wave Scattering from Random Rough Surfaces, J. A. Ogilvy)
7. Physics of Critical Phenomena (Introduction to Phase Transitions and Critical Phenomena, H. E. Stanley)
Graduate Supervision :
I : Doctoral Students
1. M. Rajabi (2011) Fabrication of ZnO nanostructures for application in ultraviolet photodetectors.
2. F. Zahedi (2012) Fabrication of ZnO nanostructure by spray pyrolysis method and study of its optoelectronic properties.
3. Zh. Ebrahiminejad (2014) The growth of rough surfaces and the study of electron transport through their interface.
4. M. Einollahzadeh (2014) Growth and characterization of titanium dioxide nanotube on transparent conductive glass.
5. S. Piri (2015) Fabrication of dye sensitized solar cell based on titanium dioxide nanostructure on quratz substrate.
6. N. Rahmani (2015) Effect of porous silicon substrate on nanostructures lattice mismatch growth.
7. H. Eynollahzadeh (2015) Study of the physical properties of two-dimensional nanostructure systems.
8. Z. Dadi (2015) Study of electrical transport of nanostructure systems.
II : Masters’ Students
1. B. Rasoli (1998) Study of electroluminescence properties of porous silicon.
2. H. Nurani (1999) Optical properties of porous silicon.
3. H. Khalili (2000) Study of photoconductivity in porous silicon.
4. S. Khoshnevis (2000) Production of gas sensor from porous silicon.
5. A. Nemati (2000) The effects of impurities on the band gap energy of CdS photoconductors.
6. Sh. Nahidinejad (2000) Approximate calculation of ground state wave function and Hartree operator eigen value for five particles system.
7. A. Phiroznia (2000) Explanation of integer quantum Hall effect in impurity systems by gauge invariance.
8. L. Moghaddasi (2001) Evaluation of resonant tunnelling transmission coefficient from multilayer structure’s GaAlAs/GaAs.
9. F. Dehghani (2002) Calculation of band structure for Be by KKR method.
10. M. H. Dabbaghian (2002) studying and investigation of the gain semiconductor multiple quantum well lasers GaAs/GaAlAs.
11. S. Mianeifard (2003) Computer simulation of the surface of porous silicon by DLA model.
12. F. Mohammadi (2003) Calculation of band structure for B by Hartree-Fock method.
13. M. Zare (2004) Photovoltaic effect from porous silicon.
14. M. Khalili (2004) Determination of transmission coeffiecient from multi quantum barrier by matrix method and calculation of current density.
15. Sh. D. Milani (2004) Optoelectronic charateristics of porous silicon surface and its role on band gap.
16. S. Asghari (2005) Calculation of optical constants of silicon and porous silicon by Kramers-Kronig method.
17. I. Hoseinzadeh (2006) Porous silicon multilayer optical waveguide.
18. M. Rajabi (2006) Fabrication and study of porous silicon solar cells.
19. N. M. Taheri (2007) Simulation of fractal like particle by DLA method.
20. L. Esmaeili (2007) Ground state energy calculation of silicon nanocluster by diffusion quantum Monte Carlo.
21. S. Farokhipoor (2007) Photoconductivity properties of silicon nanoparticles.
22. I. Bazafkan (2008) Nonlinear electrical characterization of free-standing porous silicon.
23. N. Sadeghbeigi (2008) Nonlinear electrical properties of silicon nanoparticles.
24. A. Miri (2008) Photoconductivity of silicon nanoparticles.
25. N. Rahmani (2009) Optical properties of free-standing porous silicon.
26. Z. Hosseini (2009) Electrical conductivity of free-standing porous silicon.
27. M. Einollahzadeh (2009) Capacitance properties of porous silicon nanostructure.
28. M. Kaviani (2010) Band structure calculation of porous silicon nanostructure by modified tight binding method.
29. S. Sadr (2010) Study of structural effects of porous layer due to electrochemical anodization for enhancement of porous silicon sensor sensitivity.
30. Z. Ahmadi (2011) Investigation of porous silicon nanostructures by raman scattering.
31. S. Ebrahimnasab (2011) Study of nanostructures morphology by scattering spectrum.
32. F. Khosravi (2011) Study and constracting the hydrogen gas sensor based on nanocomposite ZnO-Fe2O3 with doping palladium.
33. F. Tavakoli (2011) Dielectric relaxation of porous silicon nanostructures.
34. S. Khadivian (2011) Simulation of thin films growth under oblique angle by Monte Carlo method.
35. M. Abdollahi (2012) Zone model in nanostructures grwoth simulation.
36. R. Zafari (2012) Light absorption in porous silicon nanostructures.
37. Z. Khodam (2012) Calculation of transmission and reflection coefficients of nanostructures for multi quantum wells.
38. Sh. Ebrahim (2012) Controlled growth of ZnO nanowires and their structural morphologies.
39. Z. Nafari (2012) Fabrication and study of absorption properties of titanium dioxide nanostructures.
40. Z. Amani (2012) Calculation of gain at quantum well semiconductor laser.
41. R. Ahmadi (2012) Morphology study of nanostructured ZnO hollow fibers.
42. R. Boodaghi (2012) Calculation of current density of Ga Al As multi quantum barriers under electric potential.
43. T. Seyedi (2013) Study of SiO2 thin film properties applied on ZnO nanowires waveguide.
44. E. Easy (2013) Study of solar cell properties of TiO2 nanostructures.
45. Z. Laktarashi (2013) Micro-strain effect on porous silicon.
46. Z. Karami (2013) Fabrication and study of structural and morphological of TiO2 hollow nano fibers.
47. M. Khorani (2013) Simulation of nanostructures volume growth with diamond lattice under oblique angle by Monte Carlo method.
48. F. Mohammadinejad (2014) Studying and investigation of the current density multi quantum well semiconductor laser.
49. N. Abbas Hadi (2014) Study of electrical conduction on growth nanostructures by Monte-Carlo method.
50. M. Nazari (2014) Study of stress effect on porous silicon nanostructure.
51. Z. Emami (2014) Study of silver doping effect on CdS nanoparticles properties.
52. A. Esmaeili (2014) Study of photocatalyst effect of TiO2 nanoparticles on methylene blue.
53. F. Najafi (2015) Fabrication of silicon dioxide hollow fibers.
54. F. Faraji (2015) Study of porosity variations on electrical properties of TiO2 nano structure on porous silicon.
55. F. Salehi (2015) Study of structural and optical properties of CdS nanowires fabricated by SILAR technique.
56. M. Haditale (2015) Structural and electrical properties of graphene nanoparticles.
57. M. Zabihipour (2015) Study of electrical properties of ZnO nanostructures on porous silicon.
58. S. Emami Koli (2015) Band gap measurement of aluminum oxide nanoparticles by using absorption spectrum.
59. S. Z. Najafi Mousavi (2015) Study of temperature effect on silicon nanostructures growth simulation.