Dr. Md. Mustafizur Rahman

Professor
Bangladesh University of Engineering and Technology, Bangladesh

Highest Degree
PostDoc Fellow in Computational Fluid Dynamics from University of Malaya, Malaysia

My URL
https://livedna.org/880.12611

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Area of Interest:

Mathematics
Applied Mathematics
Computational Fluid Dynamics
Numerical Heat Transfer
Operation Research

Selected Publications

  1. Rahman, M.M., H.F. Oztop, A.H. Joarder, R. Saidur, N. Hamzah, K. Al-Salem and T.A. Ibrahim, 2016. Unsteady Analysis of Natural Convection in a Carbon nanotube-water Filled Cavity with Inclined Heater. Numer. Heat Transfer Part, 69: 794-809.
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  2. Mojumder, S., S. Saha, M.R. Rahman, M.M. Rahman and K. Md. Rabbi, 2016. Numerical study on mixed convection heat transfer in a porous L-shaped cavity. Eng. Sci. Technol. Int. J., 10.1016/j.jestch.2016.07.005.
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  3. Md. Rabbi, K., S. Saha, S. Mojumder, M.M. Rahman, R. Saidur and T.A. Ibrahim, 2016. Numerical investigation of pure mixed convection in a ferrofluid-filled lid-driven cavity for different heater configurations. Alexandria Eng. J., 55: 127-139.
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  4. Uddin, M.B., M.M. Rahman, M.A.H. Khan and T.A. Ibrahim, 2015. Effect of Buoyancy Ratio on Unsteady Thermosolutal Combined Convection in a Lid Driven Trapezoidal Enclosure in the Presence of Magnetic Field. Comput.Fluids, 114: 284-296.
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  5. Uddin, M.B., M.M. Rahman and M.A.H. Khan, 2015. Hydromagnetic Double-Diffusive Unsteady Mixed Convection in Trapezoidal Enclosure Due to Uniform and Nonuniform Heating at the Bottom Side. Numer. Heat Transfer Part, 68: 205-224.
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  6. Rahman, M.M., S. Saha, S. Mojumder, A.G. Naim, R. Saidur and T.A. Ibrahim, 2015. Effect of Sine-squared Thermal Boundary Condition on Augmentation of Heat Transfer in a Triangular Solar Collector Filled with Different Nanofluids. Numer. Heat Transfer Part, 68: 53-74.
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  7. Rahman, M.M., S. Mojumder, S. Saha, A.H. Joarder, R. Saidur and A.J. Naim, 2015. Numerical and statistical analysis on unsteady magnetohydrodynamic convection in a semi-circular enclosure filled with ferrofluid. Int. J. Heat Mass Transfer, 89: 1316-1330.
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  8. Rahman, M.M., H.F. Oztop, S. Mekhilef, R. Saidur and J. Orfi, 2015. Simulation of unsteady heat and mass transport with heatline and massline in a partially heated open cavity. Appl. Math. Modell., 39: 1597-1615.
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  9. Rahman, M.M., H.F. Oztop, R. Saidur, S. Mekhilef and K. Al-Salem, 2015. Unsteady Mixed Convection in a Porous Media Filled Lid-Driven Cavity Heated by a Semi-Circular Heaters. Therm. Sci., 19: 1761-1768.
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  10. Rahman, M.M., H.F. Oztop, M. Steele, A.G. Naim, K. Al-Salem and T.A. Ibrahim, 2015. Unsteady natural convection and statistical analysis in a CNT-water filled cavity with non-isothermal heating. Int. Commun. Heat Mass Transfer, 64: 50-60.
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  11. Shahrul, I.M., I.M. Mahbubul, R. Saidur, S.S. Khaleduzzaman, M.F.M. Sabri and M.M. Rahman, 2014. Effectiveness study of a shell and tube heat exchanger operated with nanofluids at different mass flow rates. Numer. Heat Transfer Part, 65: 699-713.
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  12. Rahman, M.M., S. Saha, S. Mojumder, S. Mekhilef and R. Saidur, 2014. Numerical Simulation of Unsteady Heat Transfer in a Half Moon Shape Enclosure with Variable Thermal Boundary Condition for Different Nanofluids. Numer. Heat Transfer Part, 65: 282-301.
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  13. Rahman, M.M., S. Mojumder, S. Saha, S. Mekhilef and R. Saidur, 2014. Effect of Solid Volume Fraction and Tilt Angle in a Quarter Circular Solar Thermal Collectors Filled with CNT-Water Nanofluid. Int. Communi. Heat Mass Transfer, 57: 79-90.
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  14. Rahman, M.M., S. Mojumder, S. Saha, S. Mekhilef and R. Saidur, 2014. Augmentation of Natural Convection Heat Transfer in Triangular Shape Solar Collector by Utilizing Water Based Nanofluids Having a Corrugated Bottom Wall. Int. Communi. Heat Mass Transfer, 50: 117-127.
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  15. Rahman, M.M., H.F. Oztop, S. Mekhilef, R. Saidur and K. Al-Salem, 2014. Unsteady Natural Convection in Al2O3-water Nanoliquid filled in Isosceles Triangular Enclosure with Sinusoidal Thermal boundary Condition on Bottom Wall. Superlattices Microstruct., 67: 181-196.
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  16. Rahman, M.M., H. Oztop, S. Mekhilef, R. Saidur, A. Ahsan and K. Al-Salem, 2014. Modeling of unsteady natural convection for double-pipe in a partially cooled enclosure. Numer. Heat Transfer, Part A: Applic. Int. J. Comput. Methodol., 66: 582-603.
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  17. Khaleduzzaman, S.S., R. Saidur, I.M. Mahbubul, T.A. Ward and M.R. Sohel et al., 2014. Energy, Exergy, and Friction Factor Analysis of Nanofluid as a Coolant for Electronics. Ind. Eng. Chem. Res., 53: 10512-10518.
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  18. Rahman, M.M., S. Parvin, M. Hasanuzzaman, R. Saidur and N.A. Rahim, 2013. Effect of heat- generating solid body on mixed convection flow in a ventilated cavity. Heat Transfer Eng., 34: 1249-1261.
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  19. Rahman, M.M., R. Saidul, S. Mekhilef, M.B. Uddin and A. Ahsan, 2013. Double-diffusive buoyancy induced flow in a triangular cavity with corrugated bottom wall: Effects of geometrical parameters. Int. Commun. Heat Mass Transfer, 45: 64-74.
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  20. Rahman, M.M., H.F. Oztop, R. Saidur, S. Mekhilef and K. Al-Salem, 2013. Finite element solution of MHD mixed convection in a channel with a fully or partially heated cavity. Comput.Fluids, 79: 53-64.
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  21. Obayedullah, M., M.M.K. Chowdhury and M.M. Rahman, 2013. Natural convection in a rectangular cavity having internal energy sources and electrically conducting fluid with sinusoidal temperature at the bottom wall. Int. J. Mech. Mater. Eng., 8: 73-78.
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  22. Obayedullah, M., M.M.K. Chowdhury and M.M. Rahman, 2013. A Comparative Study of the Effect of Linear Temperature and Parabolic Temperature at the Bottom Wall of a Rectangular Cavity Having Internal Energy Sources and Electrically Conducting Fluid. Eng. Trans., 8: 36-42.
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  23. Munshi, M.J.H., A.K. Azad, R.A. Begum, M.B. Uddin and M.M. Rahman, 2013. Modeling and simulation of MHD convective heat transfer of channel flow having a cavity. Int. J. Mech. Mater. Eng., 8: 63-72.
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  24. Khairul, M.A., R. Saidur, M.M. Rahman, M.A. Alim, A. Hossain and Z. Abdin, 2013. Heat transfer and thermodynamic analysis of a helically coiled heat exchanger using different types of nanofluids. Int. J. Heat Mass Transfer, 67: 398-403.
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  25. Farid, S.K., M.M. Billah, M.M. Rahman and U.M. Sharif, 2013. Numerical Study of Fluid Flow on Magneto-Hydrodynamic Mixed Convection in a Lid Driven Cavity Having a Heated Circular Hollow Cylinder. Procedia Eng., 56: 474-479.
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  26. Billah, M.M., M.M. Rahman, M.A. Razzak, R. Saidur and S. Mekhilef, 2013. Unsteady buoyancy-driven heat transfer enhancement of nanofluids in an inclined triangular enclosure. Int. Communi. Heat Mass Transfer, 49: 115-127.
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  27. Billah, M.M., M.M. Rahman and U.M. Sharif, 2013. Heat Transfer Enhancement of Nanofluids in a Lid- Driven Triangular Enclosure Having a Discrete Heater. Procedia Eng., 56: 330-336.
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  28. Azad, A.K., M.J.H. Munshi and M.M. Rahman, 2013. Double Diffusive Mixed Convection in a Channel with a Circular Heater. Procedia Eng., 56: 157-162.
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  29. Alam, M.S., M.A.H. Khan and M.M. Rahman, 2013. Critical Analysis of the Influence of Magnetic Reynolds Number on MHD Jeffery-Hamel Flows. Int. J. Appl. Math Mech., 9: 31-46.

  30. Ahammad, M.U., M.M. Rahman and M.L. Rahman, 2013. Mixed Convection Flow and Heat Transfer Behavior inside a Vented Enclosure in the Presence of Heat Generating Obstacle. Int. J. Innovation and Appl. Stud., 3: 967-978.
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  31. Ahammad, M.U., M. Obayedullah and M.M. Rahman, 2013. Analysis of MHD free convection flow along a vertical porous plate embedded in a porous medium with magnetic field and heat generation. Eng. Trans., 8: 10-18.
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  32. Sharif, U.M., M.M. Rahman, M.A. Saklayen, M.M. Billah and M. Elias, 2012. A numerical study of assisting MHD mixed convection inside a ventilated cavity. Eng. e-Trans., 6: 62-69.

  33. Rahman, M.M., S. Parvin, N.A. Rahim, M.R. Islam, R. Saidur and M. Hasanuzzaman, 2012. Effects of reynolds and prandtl number on mixed convection in a ventilated cavity with a heat-generating solid circular block. Appl. Math. Modell., 36: 2056-2066.
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  34. Rahman, M.M., S. Parvin, N.A. Rahim, M. Hasanuzzaman and R. Saidur, 2012. Simulation of mixed convection heat transfer in a horizontal channel with an open cavity containing a heated hollow cylinder. Heat Transfer-Asian Res., 41: 339-353.
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  35. Rahman, M.M., M.M. Billah, N.A. Rahim, R. Saidur and M. Hasanuzzaman, 2012. Finite element simulation of magneto hydrodynamic mixed convection in a double-lid driven enclosure with a square heat-generating block. ASME J. Heat Transfer, 134: 1-8.
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  36. Rahman, M.M., M.M. Billah, M. Hasanuzzaman, R. Saidur and N.A. Rahim, 2012. Heat transfer enhancement of nanofluids in a lid-driven square enclosure. Numer. Heat Transfer Part, 62: 973-991.
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  37. Rahman, M.M., H.F. Oztop, N.A. Rahim, R. Saidur and K. Al-Salem et al., 2012. Computational analysis of mixed convection in a channel with a cavity heated from different sides. Int. Commun. Heat Mass Transfer, 39: 78-84.
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  38. Rahman, M.M., H.F. Oztop, A. Ahsan, R. Saidur, K. Al-Salem and N.A. Rahim, 2012. Laminar mixed convection in inclined triangular enclosures filled with water based Cu nanofluid. Ind. Eng. Chem. Res., 51: 4090-4100.
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  39. Rahman, M.M., H.F. Oztop, A. Ahsan, M.A. Kalam and Y. Varol, 2012. Double-diffusive natural convection in a triangular solar collector. Int. Commun. Heat Mass Transfer, 39: 264-269.
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  40. Rahman, M.M., H.F. Oztop, A. Ahsan, M.A. Kalam and M.M. Billah, 2012. MHD Mixed convection in a channel with triangular cavity. Numer. Heat Transfer Part, 61: 268-282.
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  41. Rahman, M.M., H.F. Oztop, A. Ahsan and J. Orfi, 2012. Natural convection effects on heat and mass transfer in a curvilinear triangular cavity. Int. J. Heat Mass Transfer, 55: 6250-6259.
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  42. Oztop, H.F., M.M. Rahman, A. Ahsan, M. Hasanuzzaman, R. Saidur, K. Al-Salem and N.A. Rahim, 2012. MHD natural convection in an enclosure from two semi-circular heaters on the bottom wall. Int. J. Heat Mass Transfer, 55: 1844-1854.
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  43. Hasanuzzaman, M., M.M. Rahman, H.F. Oztop, N.A. Rahim and R. Saidur, 2012. Effects of Lewis number on heat and mass transfer in a triangular cavity. Int. Communi. Heat Mass Transfer, 39: 1213-1219.
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  44. Hasanuzzaman, M., H.F. Oztop, M.M. Rahman, N.A. Rahim, R. Saidur and Y. Varol, 2012. Magnetohydrodynamic natural convection in trapezoidal cavities. Int. Commun. Heat Mass Transfer, 39: 1384-1394.
    CrossRef  |  

  45. Ching, Y.C., H.F. Oztop, M.M. Rahman, M.R. Islam and A. Ahsan, 2012. Finite element simulation of mixed convection heat and mass transfer in a right triangular enclosure. Int. Commun. Heat Mass Transfer, 39: 689-696.
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  46. Billah, M.M., M.J.H. Munshi, A.R. Khan, A. Rashid and M.M. Rahman, 2012. Mathematical modeling for heat transfer enhancement in a ventilated enclosure with a circular heat-generating block. Eng. e-Trans., 7: 54-61.
    Direct Link  |  

  47. Billah, M.M., M.J.H. Munshi, A.K. Azad, M.S. Uddin and M.M. Rahman, 2012. Numerical simulation of magneto-hydrodynamics mixed convection in an open channel having a semi-circular heater. J. Naval Archit. Mar. Eng., 9: 1-10.
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  48. Alam, M.S., M.M. Billah and M.M. Rahman, 2012. Effect of inlet and outlet positions on MHD mixed convection in a ventilated cavity. Jagannath Univ. J. Sci., 1: 83-95.

  49. Ahammad, M.U., M.M. Rahman and M.L. Rahman, 2012. Effect of inlet and outlet position in a ventilated cavity with a heat generating square block. Eng. Trans., 7: 107-115.
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  50. Rahman, M.M., S. Parvin, R. Saidur and NA. Rahim, 2011. Magnetohydrodynamic mixed convection in a horizontal channel with an open cavity. Int. Commun. Heat Mass Transfer, 38: 184-193.
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  51. Rahman, M.M., R. Saidur and N.A. Rahim, 2011. Conjugated effect of joule heating and magneto- hydrodynamic on double-diffusive mixed convection in a horizontal channel with an open cavity. Int. J. Heat Mass Transfer, 54: 3201-3213.
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  52. Rahman, M.M., N.A. Rahim, S. Saha, M.M. Billah, R. Saidur and A. Ahsan, 2011. Optimization of mixed convection in a lid-driven enclosure with a heat generating circular body. Numer. Heat Transfer, Part A: Applic., 60: 629-650.
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  53. Rahman, M.M., M.M. Billah, N.A. Rahim, N. Amin, R. Saidur and M. Hasanuzzaman, 2011. A Numerical model for the simulation of double-diffusive natural convection in a right-angled triangular solar collector. Int. J. Renewable Energy Res., 1: 14-18.
    Direct Link  |  

  54. Rahman, M.M., M.M. Billah, A.T.M.M. Rahman, M.A. Kalam and A. Ahsan, 2011. Numerical investigation of heat transfer enhancement of nanofluids in an inclined lid-driven triangular enclosure. Int. Commun. Heat Mass Transfer, 38: 1360-1367.
    CrossRef  |  Direct Link  |  

  55. Rahman, M.M., M.A.H. Mamun and R. Saidur, 2011. Analysis of magnetohydrodynamic mixed convection and joule heating in lid-driven cavity having a square block. J. Chin. Inst. Eng., 35: 585-599.
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  56. Rahman, M.M., M.A. Alim and M.M. Billah, 2011. Effect of Reynolds and Prandtl numbers on mixed convection in an obstructed vented cavity. J. Sci. Res., 3: 271-281.
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  57. Rahman, M.M., M. Elias and M.A. Alim, 2011. Mixed convection flow in a rectangular ventilated cavity with a heat conducting circular cylinder at the centre. IJE Trans. Appli., 24: 93-105.

  58. Rahman, M.M., H.F. Oztop, R. Saidur, N.A. Rahim and K. Al-Salem, 2011. MHD mixed convection with joule heating effect in a lid-driven cavity with a heated semi-circular source using finite element technique. Numer. Heat Transfer, 60: 543-560.
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  59. Hossain, M.S., R. Saidur, H. Fayaz, M.M Rahman, N. A. Rahim and M.R. Islam, 2011. Review on solar water heater collector and thermal energy performance of circulating pipe. Renewable Sustainable Energy Rev., 15: 3801-3812.
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  60. Farid, S.K., M.M. Billah, M.Z.I. Khan, M.M. Rahman and U.M. Sharif, 2011. A numerical analysis of cooling water temperature of two-stage adsorption chiller along with different mass ratios. Int. Communi. Heat Mass Transfer, 38: 1086-1092.
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  61. Billah, M.M., M.M. Rahman, U.M. Sharif, N.A. Rahim, R. Saidur and M. Hasanuzzaman, 2011. Numerical analysis of fluid due to mixed convection in a lid-driven cavity having a heated circular hollow cylinder. Int. Communi. Heat Mass Transfer, 38: 1093-1103.
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  62. Billah, M.M., M.M. Rahman, R. Saidur and M. Hasanuzzaman, 2011. Simulation of MHD mixed convection heat transfer enhancement in a double lid-driven obstructed enclosure. Int. J. Mech. Mater. Eng., 6: 18-30.
    Direct Link  |  

  63. Billah, M.M., M.M. Rahman, M. Shahabuddin and A.K. Azad, 2011. Heat Transfer Enhancement of Copper-Water Nanofluids in an Inclined Lid-Driven Triangular Enclosure. J. Sci. Res., 3: 535-548.
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  64. Billah, M.M., M.M. Rahman, J.U. Ahamed and M.M.K. Bhuiya, 2011. MHD mixed convection heat transfer enhancement in a lid-driven enclosure having a heat-generating body: aspect ratio and Prandtl number effect. Int. J. Energy Technol., 3: 1-8.

  65. Billah, M.M., M.M. Rahman and M.S. Uddin, 2011. An Analysis of Assisting MHD Mixed Convection inside a Ventilated Cavity with Different Inlet and Exit Configurations. Jahangirnagar Univ. J. Sci., 34: 73-78.

  66. Billah, M.M., M.M. Rahman and M.A. Uddin, 2011. Mixed convection inside a ventilated cavity along with a centered heat conducting horizontal circular cylinder. Eng. e-Trans., 6: 62-69.
    Direct Link  |  

  67. Billah M.M., M.M. Rahman, M.H. Kabir and U.M. Sharif, 2011. Heat transfer and flow characteristics for MHD mixed convection in a lid-driven cavity with heat generating obstacle. Int. J. Energy Technol., 3: 1-8.

  68. Rahman, M.M., R. Nasrin and M.M. Billah, 2010. Effect of Prandtl number on hydromagnetic mixed convection in a double lid-driven cavity with a heat-generating obstacle. Eng. e-Trans., 5: 90-96.
    Direct Link  |  

  69. Rahman, M.M., M.A.H. Mamun, M.M. Billah and R. Saidur, 2010. Natural convection flow in a square cavity with internal heat generation and a flush mounted heater on a side wall. J. Naval Archit. Mar. Eng., 7: 37-50.
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  70. Rahman, M.M., M.A. Alim and S. Saha, 2010. Mixed convection in a square cavity with a heat conducting horizontal square cylinder. Suranaree J. Sci. Technol., 17: 139-153.
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  71. Rahman, M.M., M.A. Alim and M.M.A. Sarker, 2010. Numerical study on the conjugate effect of joule heating and magnato hydro dynamics mixed convection in an obstructed lid-drivens quare cavity. Int. Commun. Heat Mass Transfer, 37: 524-534.
    CrossRef  |  

  72. Rahman, M.M. and M.A. Alim, 2010. MHD mixed convection flow in a vertical lid-driven square enclosure including a heat conducting horizontal circular cylinder with joule heating. Nonlinear Anal. Modell. Control, 15: 199-211.
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  73. Mamun, M.A.H., T.R. Tanim, M.M. Rahman, R. Saidur and S. Nagata, 2010. Mixed convection analysis in trapezoidal cavity with a moving lid. Int. J. Mech. Mater. Eng., 5: 18-28.
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  74. Mamun, M.A.H., M.T. Islam and M.M. Rahman, 2010. Natural convection in a porous trapezoidal enclosure with magneto-hydrodynamic effect. Nonlinear Anal. Modell. Control, 15: 159-184.
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  75. Mamun, M.A.H., M.M. Rahman, M.M. Billah and R. Saidur, 2010. A numerical study on the effect of a heated hollow cylinder on mixed convection in a ventilated cavity. Int. Commun. Heat Mass Transfer, 37: 1326-1334.
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  76. Rahman, M.M., M.A.H. Mamun, R. Saidur and S. Nagata, 2009. Effect of a heat conducting horizontal circular cylinder on MHD mixed convection in a lid-driven cavity along with joule heating. Int. J. Mech. Mater. Eng., 4: 256-265.

  77. Rahman, M.M., M.A. Alim, S. Saha and M.K. Chowdhury, 2009. Effect of the presence of a heat conducting horizontal square block on mixed convection inside a vented square cavity. Nonlinear Anal. Modell. Control, 14: 531-548.
    Direct Link  |  

  78. Rahman, M.M., M.A. Alim and M.K. Chowdhury, 2009. Magnetohydrodynamics mixed convection around a heat conducting horizontal circular cylinder in a rectangular lid-driven cavity with joule heating. J. Sci. Res., 1: 461-472.
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  79. Rahman, M.M., M.A. Alim and M.A.H. Mamun, 2009. Finite element analysis of mixed convection in a rectangular cavity with a heat-conducting horizontal circular cylinder. Nonlinear Anal. Modell. Control, 14: 217-247.
    Direct Link  |  

  80. Rahman, M.M., M. Elias and M.A. Alim, 2009. Mixed convection flow in a rectangular ventilated cavity with a heat conducting square cylinder at the center. ARPN J. Eng. Appl. Sci., 4: 20-29.

  81. Rahman, M.M., M.A. Alim, S. Saha and M.K. Chowdhury, 2008. Mixed convection in a vented square cavity with a heat conducting horizontal solid circular cylinder. J. Naval Archit. Mar. Eng., 5: 37-46.
    CrossRef  |  Direct Link  |  

  82. Rahman, M.M., M.A. Alim, S. Saha and M.K. Chowdhury, 2008. A numerical study of mixed convection in a square cavity with a heat conducting square cylinder at different locations. J. Mech. Eng. Inst. Eng. Bangladesh, 39: 78-85.
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  83. Islam, M.T., S. Saha, G. Saha, M.M. Rahman, M.A.H. Mamun and M.Q. Islam, 2008. Numerical simulation on mixed convection in a parallelogrammic Ventilated Enclosure. Ganit J. Bangladesh Math. Soc., 28: 45-58.

  84. Rahman, M.M., M.A. Alim, M.A.H. Mamun, M.K. Chowdhury and A.K.M.S. Islam, 2007. Numerical study of opposing mixed convection in a vented enclosure. ARPN J. Eng. Appl. Sci., 2: 25-36.

  85. Rahman, M.M., M.A. Hye and M.A.H. Khan, 2006. Approximant methods and singularity analysis of power series. Ganit J. Bangladesh Math, 26: 11-28.

  86. Rahman, M.M. and M.A.H. Khan, 2004. A new approach to partial differential approximants. Ganit J. Bangladesh Math. Soc., 24: 55-65.
Member since September, 2016