مقالات بین المللی (JCR, Scopus)

1. M. Mohseni, and Amir Hossein Fathollahi, Experimental Investigation of Fe₃O₄ Nano-Oil and Outdoor Temperature Effects on a 5-Ton R22 Vapor Compression Chiller Performance, Scientific Reports (2025) 15:21027.
2. M. Mohseni, ‘Exact thermodynamic solution of gas behavior in propellant tanks and storage capsules during pressurization’, International Journal of Thermodynamics, Vol. 28 (No. 1), pp. 007-016, 2025.
3. Hamid-Reza Bahrami and M. Mohseni, ‘Exploring impacts of using porous media on heat transfer in helical coils: a comprehensive numerical study’, Journal of Porous Media 28(4):35–64 (2025). 
4. M. Mohseni, Hamid-Reza Bahrami, and Mohammad Sadegh Leili, ‘Energy and exergy analysis of a steam power plant to replace the boiler with a heat recovery steam generator’, Int. J. Exergy, Vol. 43, No. 1, 2024.
5. M. Mohseni and Ali Amini, ‘Performance of different wall functions in turbulent flow inside a pipe, a diffuser, and behind a backward-facing step’, Progress in Computational Fluid Dynamics, An International Journal, Vol. 24, No. 2, 2024.
6. M. Mohseni, M. K. Domfeh, ‘Numerical analysis of transient vortex formation at the outlet of a tank containing gas-liquid phases’, Journal of Applied Fluid Mechanics, Vol. 16(11), pp. 2235-2248, 2023. 
7. M. Mohseni, ‘Thermal Behavior of Laminar Flow of Supercritical CO2 in a Long Vertical Mini-Pipe under Constant and Stepped Wall Heat Flux’, Heat and Mass Transfer Research, Vol. 9 (2), 2022, pp. 245-254.
8. M. Zolfaghar and M. Mohseni, ‘Numerical study of the effect of hole arrangement in a pipe containing perforated porous media’, Thermal Science and Engineering Progress, Vol. 25, 2021. 
9. M. Mohseni and M. Bazargan, ‘A New Correlation for the Turbulent Prandtl Number in Upward Rounded Tubes in Supercritical Fluid Flows’, ASME J of Heat Transfer, 2016; 138(8):081701-081701-9. DOI: 10.1115/1.4033137.
10. M. Mohseni and M. Bazargan,  ‘Entropy Generation in Turbulent Mixed Convection Heat Transfer to highly Variable Property Pipe Flow of Supercritical Fluids’, Energy Conversion and Management 87 (2014) 552-558. 
11. M. Mohseni and M. Bazargan, ‘A New Analysis of Heat Transfer Deterioration on Basis of Turbulent Viscosity Variations of Supercritical Fluids’, Journal of Heat Transfer, T-ASME, 2012; 134(12):122503-122503-7, doi: 10.1115/1.4007313.
12. M. Bazargan and M. Mohseni, ‘Algebraic Zero-Equation Versus Complex Two-Equation Turbulence Modeling in Supercritical Fluid Flows’, Computers & Fluids 60 (2012) 49–57.
13. M. Mohseni and M. Bazargan, ‘Modifications of Low Reynolds Number k-ε Turbulence Models for Applications in Supercritical Fluid Flows’, Int. J. Thermal Sciences 51 (2012) 51-62. 
14. M. Mohseni and M. Bazargan, ‘New analysis of heat transfer deterioration based on supercritical fluid property variations’, Journal of Thermophysics and Heat Transfer (AIAA), 2012, Vol. 26, 197-200.
15. M. Mohseni and M. Bazargan, ‘Effect of Turbulent Prandtl Number on Convective Heat Transfer to Turbulent flow of a Supercritical Fluid in a Vertical Round Tube’, J. Heat Transfer, T-ASME, 2011; 133(7):071701-071701-10. doi: 10.1115/1.4003570.
16. M. Mohseni and M. Bazargan, ‘The effect of the low Reynolds number k-e turbulence models on simulation on enhanced and deteriorated convective heat transfer to the supercritical fluid flows’, Heat and Mass Transfer, 2010, Vol. 47, No. 5, pp. 609-619.
17. H. Karimi, A. Nassirharand, M. Mohseni, ‘Modeling and simulation of a class of liquid propellant engine pressurization systems’, Acta Astronautica 66 (2010) 539-549.
18. M. Bazargan and M. Mohseni, ‘The significance of the buffer zone of boundary layer on convective heat transfer to a vertical turbulent flow of a supercritical fluid’, The Journal of Supercritical Fluids 51 (2009) 221-229.