1- Goudarzi, S., Yekani Motlagh, S. and Soltanipour, H., 2022. Two-phase simulation of MHD and FHD impacts on the natural convection of a magnetic nanofluid within a porous cavity. Mechanical engineering, 6(1), pp.9-9.

2- Jalayeri Gharahghonlou, A., Soltanipour, H. and Rezazadeh, S., 2021. Numerical investigation of turbulent nanofluid flow and nanoparticle diameter on heat transfer in a wavy form channel. نشریه پژوهشی مهندسی مکانیک ایران.&lrm

3- Soltanipour, H., 2021. Numerical analysis of two-phase ferrofluid forced convection in an annulus subjected to magnetic sources. Applied Thermal Engineering, 196, p.117278.

4- Abdi, H., Motlagh, S.Y. and Soltanipour, H., 2021. Numerical study of two-phase flow in a square cavity under magnetic field of parallel wires. Meccanica, 56(8), pp.2005-2020.

5- Soltanipour, H. and Pourfattah, F., 2021. Simultaneous use of non-uniform magnetic field and porous medium for the intensification of convection heat transfer of a magnetic nanofluid inside a tube. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 43(10), pp.1-19.

6- Mehdizadeh Youshanlouei, M., Yekani Motlagh, S. and Soltanipour, H., 2021. The effect of magnetic field on the performance improvement of a conventional solar still: a numerical study. Environmental Science and Pollution Research, 28(24), pp.31778-31791.

7- Soltanipour, H., 2020. Two-phase simulation of magnetic field effect on the ferrofluid forced convection in a pipe considering Brownian diffusion, thermophoresis, and magnetophoresis. The European Physical Journal Plus, 135(9), pp.1-23.

8- Abdi, H., Motlagh, S.Y. and Soltanipour, H., 2020. Study of magnetic nanofluid flow in a square cavity under the magnetic field of a wire carrying the electric current in turbulence regime. Results in Physics, 18, p.103224.

9- Soltanipour, H., Gharegöz, A. and Oskooee, M.B., 2020. Numerical study of magnetic field effect on the ferrofluid forced convection and entropy generation in a curved pipe. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 42(3), pp.1-15.

10- Habibinia, D., Rostami, N., Feyzi, M.R., Soltanipour, H. and Pyrhönen, J., 2019. New finite element based method for thermal analysis of axial flux interior rotor permanent magnet synchronous machine. IET Electric Power Applications, 14(3), pp.464-470.

11- Motlagh, S.Y., Taghizadeh, S. and Soltanipour, H., 2016. Natural convection heat transfer in an inclined square enclosure filled with a porous medium saturated by nanofluid using Buongiorno&rsquos mathematical model. Advanced Powder Technology, 27(6), pp.2526-2540.

12- Motlagh, S.Y. and Soltanipour, H., 2017. Natural convection of Al2O3-water nanofluid in an inclined cavity using Buongiorno's two-phase model. International Journal of Thermal Sciences, 111, pp.310-320.

13- Soltanipour, H., Khalilarya, S., Yekani Motlagh, S. and Mirzaee, I., 2017. The effect of position-dependent magnetic field on nanofluid forced convective heat transfer and entropy generation in a microchannel. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 39, pp.345-355.

15- Soltanipour, H., Pourmahmoud, N. and Mirzaee, I., 2015. The effects of longitudinal fins on thermal performance of a curved microchannel: a numerical study. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 229(5), pp.906-915.

16- Pourmahmoud, N., Soltanipour, H. and Mirzaee, I., 2016. The effects of longitudinal ribs on entropy generation for laminar forced convection in a microchannel. Thermal Science, 20(6), pp.1963-1972.

17- Razavi, E.S., Soltanipour, H. and Choupani, P., 2015. Second law analysis of laminar forced convection in a rotating curved duct. Thermal Science, 19(1), pp.95-107.

18- Soltanipour, H., Choupani, P. and Mirzaee, I., 2012. Numerical analysis of heat transfer enhancement with the use of &gamma-Al2O3/water nanofluid and longitudinal ribs in a curved duct. Thermal science, 16(2), pp.469-480.