Dr. Mohammad Ferdows

Visiting Professor
Louisiana Tech University, USA

Highest Degree
Ph.D. in Mechanical Engineering from Tokyo Metropolitan University, Japan

My URL
https://livedna.org/880.14850

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Area of Interest:

Engineering
Mathematical Modeling
Nanomaterial Problems
Mechanical Engineering
Fluid Mechanics

Selected Publications

  1. Ferdows, M., T.S. Khalequ, E.E. Tzirtzilakis and S. Sun, 2017. Effects of radiation and thermal conductivity on MHD boundary layer flow with heat transfer along a vertical stretching sheet in a porous medium. J. Eng. Thermophysics, 26: 96-106.
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  2. Yasmin, D., T. Ahmed, N.N. Anika, M. Ferdows and M.M. Alam, 2016. Visco-elastic fluid flow on mhd free convection and mass transfer flow with thermal and mass diffusion. Ann. Faculty Eng. Hunedoara, 14: 191-202.
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  3. Uddin, M.J., M. Ferdows, M.M. Rashidi and A.B. Parsa, 2016. Group analysis and numerical solution of slip flow of a nanofluid in porous media with heat transfer. Progr. Comput. Fluid Dynamics Int. J., 16: 190-200.
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  4. Khan, S., I. Karim, M. Alam, M. Ferdows, E. Tzirtzilakis and S. Sun, 2016. Rotationg fluid flow on MHD radiative nanofluid past a stretching sheet. Int. J. Adv. Thermofluid Res., 1: 15-30.

  5. Khan, S., I. Karim, M. Alam, E.E. Tzirtzilakis and M. Ferdows, 2016. Finite difference simulation of MHD radiative flow of a nanofluid past a stretching sheet with stability analysis. Int. J. Adv. Thermofluid Res., 1: 31-46.

  6. Ferdows, M., T.S. Khaleque and M.Z.I. Bangalee, 2016. Similarity solution on MHD boundary layer over stretching surface considering heat flux. Int. J. Heat Technol., 34: 521-526.
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  7. Ferdows, M., D. Liu and B.R. Ramachandran, 2016. Boundary layer slip and heat transfer in stagnation point flow over a steady stretching surface embedded in a porous medium with heat sources. Br. J. Math. Comput., 18: 1-8.

  8. Ferdows, M. and M.A.A. Hamad, 2016. MHD flow and heat transfer of a power-law non-Newtonian nanofluid (Cu-H2O) over a vertical stretching sheet. J. Applied Mech. Technical Phys., 57: 603-610.
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  9. Ferdows, M. and K. Vajravelu, 2016. MHD convection heat and mass transfer at a stretching sheet in a saturated porosity medium. Acta Technica, 61: 1-15.

  10. Beg, O.A., M. Ferdows, E.T.A. Beg, T. Ahmed, M. Wahiduzzaman and M.M. Alam, 2016. Numerical investigation of radiative optically-dense transient magnetized reactive transport phenomena with cross diffusion, dissipation and wall mass flux effects. J. Taiwan Inst. Chem. Eng., 66: 12-26.
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  11. Ferdows, M., M.A.A. Hamad and M. Ali, 2015. Lie group analysis on Brownian motion and thermophoresis effect on free convective boundary-layer flow on a vertical cylinder embedded in a nanofluid-saturated porous medium. J. Applied Math., Vol. 2015. 10.1155/2015/741352.
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  12. Afikuzzaman, M., M. Ferdows and M.M. Alam, 2015. Unsteady MHD casson fluid flow through a parallel plate with hall current. Procedia Eng., 105: 287-293.
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  13. Wahiduzzaman, M., M.M. Alam, M. Ferdows, S. Sivasankaran and O.A. Beg, 2014. Spectral numerical study of Non-isothermal flow through a rotating rectangular cross section. Int. J. Applied Math. Mech., 10: 61-78.

  14. Wahiduzzaman, M., M. Kamruzzaman, M.M. Alam and M. Ferdows, 2014. Magnetic field effect on fluid flow through a rotating rectangular straight duct with large aspect ratio. Progr. Comput. Fluid Dynamics Int. J., 14: 398-405.
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  15. Rashidi, M.M., M. Ferdows, A.B. Parsa and S. Abelman, 2014. MHD natural convection with convective surface boundary condition over a flat plate. Abstract Applied Anal., Vol. 2014. 10.1155/2014/923487.
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  16. Rashidi, M.M., E. Momoniat, M. Ferdows and A. Basiriparsa, 2014. Lie group solution for free convective flow of a nanofluid past a chemically reacting horizontal plate in a porous media. Math. Problems Eng., Vol. 2014. 10.1155/2014/239082.
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  17. Olajuwon, B.I., J.I. Oahimire and M. Ferdow, 2014. Effect of thermal radiation and Hall current on heat and mass transfer of unsteady MHD flow of a viscoelastic micropolar fluid through a porous medium. Eng. Sci. Technol. Int. J., 17: 185-193.
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  18. Ferdows, M., S.M. Chapal and A.A. Afify, 2014. Boundary layer flow and heat transfer of a nanofluid over a permeable unsteady stretching sheet with viscous dissipation. J. Eng. Thermophys., 23: 216-228.
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  19. Ferdows, M., M.Z.I. Bangalee and R.A. Quadir, 2014. Flow over a streaming stretching surface with slip boundary conditions and suction/injection effects. Adv. Theor. Applied Mech., 7: 39-52.
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  20. Ferdows, M., M.S. Khan, O.A. Beg, M.A.K. Azad and M.M. Alam, 2014. Numerical study of transient magnetohydrodynamic radiative free convection nanofluid flow from a stretching permeable surface. Proc. Inst. Mech. Eng. Part E: J. Process Mech. Eng., 228: 181-196.
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  21. Ferdows, M. and R.A. Quadir, 2014. Magnetic natural convection flow along insulated plate with variable thermal conductivity. Adv. Applic. Fluid Mech., 15: 1-15.
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  22. Beg, O.A., M.S. Khan, I. Karim, M.M. Alam and M. Ferdows, 2014. Explicit numerical study of unsteady hydromagnetic mixed convective nanofluid flow from an exponentially stretching sheet in porous media. Applied Nanosci., 4: 943-957.
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  23. Beg, O.A., M.M. Hoque, M. Wahiduzzaman, M.M. Alam and M. Ferdows, 2014. Spectral numerical simulation of magneto-physiological laminar Dean flow. J. Mech. Med. Biol., Vol. 14. 10.1142/S021951941450047X.
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  24. Beg, O.A., M. Ferdows, S. Shamima and M.N. Islam, 2014. Numerical simulation of Marangoni magnetohydrodynamic bio-nanofluid convection from a non-isothermal surface with magnetic induction effects: A bio-nanomaterial manufacturing transport model. J. Mech. Med. Biol., Vol. 14. 10.1142/S0219519414500390.
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  25. Bangalee, M.Z.I., J.J. Miau, S.Y. Lin and M. Ferdows, 2014. Effects of lateral window position and wind direction on wind-driven natural cross ventilation of a building: A computational approach. J. Comput. Eng., Vol. 2014. 10.1155/2014/310358.
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  26. Awual, M.R., I.M. Rahman, T. Yaita, M.A. Khaleque and M. Ferdows, 2014. pH dependent Cu (II) and Pd (II) ions detection and removal from aqueous media by an efficient mesoporous adsorbent. Chem. Eng. J., 236: 100-109.
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  27. Afify, A.A., M.J. Uddin and M. Ferdows, 2014. Scaling group transformation for MHD boundary layer flow over permeable stretching sheet in presence of slip flow with Newtonian heating effects. Applied Math. Mech., 35: 1375-1386.

  28. Wahiduzzaman, M., M.M. Alam, M. Ferdows and S. Sivasankaran, 2013. Non-isothermal flow through a rotating straight duct with wide range of rotational and pressure driven parameters. Comput. Math. Math. Phys., 53: 1571-1589.
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  29. Wahiduzzaman, M., M. Kamruzzaman, M. Alam and M. Ferdows, 2013. Magnetic effect on direct numerical simulations of fluid flow through a rotating rectangular straight duct. Int. J. Applied Electromagnetics Mech., 42: 327-342.
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  30. Wahiduzzaman, M., M. Alam, M. Ferdows, M. Hossain and R.A. Quadir, 2013. Numerical solution of fluid flow through a rotating rectangular straight duct with magnetic field. Int. J. Mech. Eng., 1: 69-86.

  31. Khan, W.A., M.A. Hamad and M. Ferdows, 2013. Heat transfer analysis for Falkner-Skan boundary layer nanofluid flow past a wedge with convective boundary condition considering temperature-dependent viscosity. Proc. Inst. Mech. Eng. Part N: J. Nanoeng. Nanosyst., 227: 19-27.

  32. Khan, M.S., M.M. Alam and M. Ferdows, 2013. Effects of magnetic field on radiative flow of a nanofluid past a stretching sheet. Procedia Eng., 56: 316-322.
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  33. Hoque, M.M., M.M. Alam, M. Ferdows and O.A. Beg, 2013. Numerical simulation of Dean number and curvature effects on magneto-biofluid flow through a curved conduit. Proc. Inst. Mech. Eng. Part H: J. Eng. Med., 227: 1155-1170.
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  34. Haque, M.M., M.M. Alam, M. Ferdows and Q.M. Al-Mdallal, 2013. Numerical simulation and stability analysis on MHD free convective heat and mass transfer unsteady flow through a porous medium in a rotating system with induced magnetic field. Int. J. Applied Electromagnetics Mech., 41: 121-141.
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  35. Ferdows, M., S. Islam and R.A. Quadir, 2013. Similarity solutions of marangoni heat transfer flow of water based nanofluid containing nanoparticles with variable viscosity and thermal conductivity. Int. Rev. Mech. Eng., 7: 692-697.

  36. Ferdows, M., P. Nag, A. Postelnicu and K. Vajravelu, 2013. Hydro-magnetic convection heat transfer in a micropolar fluid over a vertical plate. J. Applied Fluid Mech., 6: 285-299.
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  37. Ferdows, M., M.J. Uddin and T.S. Khaleque, 2013. Double diffusion, slips and variable diffusivity effects on combined heat mass transfer with variable viscosity via a point transformation. Progr. Comput. Fluid Dynamics Int. J., 13: 54-64.
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  38. Ferdows, M., M.J. Uddin and A.A. Afify, 2013. Scaling group transformation for MHD boundary layer free convective heat and mass transfer flow past a convectively heated nonlinear radiating stretching sheet. Int. J. Heat Mass Transfer, 56: 181-187.
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  39. Ferdows, M., J. Uddin, M.M. Rashidi and N. Rahimzadehc, 2013. Numerical analysis of mixed convection over horizontal moving porous flat plate by the method of one parameter continuous group theory. Int. J. Numerical Methods Heat Fluid Flow, 23: 729-749.
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  40. Ferdows, M., 2013. Steady laminar boundary layer flow over an impulsively stretching surface enclosed by strong magnetic field. Procedia Eng., 56: 281-286.
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  41. Awual, M.R., M.A. Khaleque, M. Ferdows, A.S. Chowdhury and T. Yaita, 2013. Rapid recognition and recovery of gold (III) with functional ligand immobilized novel mesoporous adsorbent. Microchemical J., 110: 591-598.
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  42. Rashidi, M.M., N. Rahimzadeh, M. Ferdows, M.J. Uddin and O.A. Beg, 2012. Group theory and differential transform analysis of mixed convective heat and mass transfer from a horizontal surface with chemical reaction effects. Chem. Eng. Commun., 199: 1012-1043.
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  43. Jahan, E., M. Ferdows, M.A.A. Hamad and A. Postelnicu, 2012. Magneto micro-polar flow considering weak concentration over a vertical porous surface in the presence of viscous dissipation and Ohmic heating: Effects of Hall and ion-slip currents. Progr. Comput. Fluid Dynamics Int. J., 12: 415-426.
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  44. Haque, M.Z., M.M. Alam, M. Ferdows and A. Postelnicu, 2012. Micropolar fluid behaviors on steady MHD free convection and mass transfer flow with constant heat and mass fluxes, joule heating and viscous dissipation. J. King Saud Univ. Eng. Sci., 24: 71-84.
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  45. Hamad, M.A.A. and M. Ferdows, 2012. Similarity solutions to viscous flow and heat transfer of nanofluid over nonlinearly stretching sheet. Applied Math. Mech., 33: 923-930.
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  46. Hamad, M.A.A. and M. Ferdows, 2012. Similarity solution of boundary layer stagnation-point flow towards a heated porous stretching sheet saturated with a nanofluid with heat absorption/generation and suction/blowing: A Lie group analysis. Commun. Nonlinear Sci. Numerical Simulation, 17: 132-140.
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  47. Ferdows, M., S.M. Chapal, M.A.A. Hamad and R.A. Quadir, 2012. Dufour and soret effect on double-diffusive electrically conducting boundary layer flows in a vertical plate considering internal heat and mass generation. IOSR J. Math., 4: 53-64.

  48. Ferdows, M., M.S. Khan, M.M. Alam and S. Sun, 2012. MHD mixed convective boundary layer flow of a nanofluid through a porous medium due to an exponentially stretching sheet. Math. Problems Eng., 3: 2551-2557.

  49. Ferdows, M., M.A.A. Hamad, S.M. Chapal and M. Ota, 2012. Similarity solutions of the incompressible boundary layer slip conditions for a vertical surface with internal heat generation & temperature dependent viscosity. Int. J. Math. Arch., 3: 2420-2424.

  50. Ferdows, M., M.A. Hamad, S.M. Chapal and M. Ota, 2012. Similarity solution of the incompressible boundary layer slips conditions for vertical surface with internal heat generation and variable suction. Int. J. Math. Arch., 3: 2407-2411.

  51. Ferdows, M., 2012. Similarity solution on free convective heat transfer flow through porosity medium. Int. J. Math. Arc., 37: 2551-2557.

  52. Ferdows, M. and T. Grosan, 2012. Viscous dissipation and heat source/sink effects on flow over stretching sheet. Int. J. Math. Arch., 3: 2466-2469.
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  53. Ferdows, M. and Q.M. Al-Mdallal, 2012. Effectsof order of chemical reaction on a boundary layer flow with heat and mass transfer over a linearly stretching sheet. Am. J. Fluid Dynamics, 2: 89-94.
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  54. Begum, A., M.A. Maleque, M. Ferdows and M. Ota, 2012. Pressure effects on unsteady free convection and heat transfer flow of an incompressible fluid past a semi-infinite inclined plate with impulsive and uniformly accelerated motion. Applied Math. Sci., 6: 3347-3365.

  55. Begum, A., M.A. Maleque, M. Ferdows and M. Ota, 2012. Finite difference solution of natural convection flow over a heated plate with different inclination and stability analysis. Applied Math. Sci., 6: 3367-3379.
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  56. Sultana, M., M.M. Haque, M.M. Alam, M. Ferdows and A. Postelnicu, 2011. Micropolar fluid behavior on MHD heat transfer flow through a porous medium with induced magnetic field by finite difference method. Eur. J. Scient. Res., 53: 477-490.

  57. Sattar, M.A. and M. Ferdows, 2011. A new class of similarity solutions of an unsteady electrically conducting free-forced convective flow in a vertical porous surface with Dufour and Soret effects. Chem. Eng. Commun., 198: 1146-1167.
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  58. Haque, M.M., M.M. Alam, M. Ferdows and A. Postelnicu, 2011. MHD free convective heat generating unsteady micropolar fluid flow through a porous medium with constant heat and mass fluxes. Eur. J. Sci. Res., 53: 491-515.

  59. Ferdows, M., V.K. Sin, M.Z.I. Bangalee and M. Ota, 2011. Further results on order of chemical reaction, thermophoresis and Radiation on the variable viscosity on heat and mass transfer flow Over an inclined surface with darcian effects. Can. J., 2: 94-113.
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  60. Ferdows, M., N. Hasan and M. Ota, 2011. Thermophoresis and chemical reaction effects on mhd natural convective heat and mass transfer flow in a rotating fluid considering heat and mass fluxes. Can. J. Sci. Eng. Math., 2: 114-139.

  61. Ferdows, M., M.Z.I. Bangalee, J.C. Crepeau and M.A. Seddeek, 2011. The effect of variable viscosity in double diffusion problem of MHD from a porous boundary with internal heat generation. Progr. Comput. Fluid Dyn., 11: 54-65.
    CrossRef  |  Direct Link  |  

  62. Ferdows, M., E. Jahan, M.A.A. Hamad and M. Ota, 2011. Effects of Hall and ion-slip currents on free convective heat transfer flow past a vertical plate considering slip conditions. Can. J. Sci. Eng. Math., 2: 70-76.
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  63. Ferdows, M., A. Postelnicu and S. Sivasankaran, 2011. Radiation effects on natural convection in an inclined porous surface with internal heat generation. World Applied Sci. J., 13: 957-961.

  64. Ferdows, M. and B.I. Olajuwon, 2011. On the similarity solution of micropolar power law fluid over a vertical plate. Int. J. Contemp. Math. Sci., 6: 133-143.
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  65. Ferdows, M., M. Hossain, S. Sivasankaran and M. Ota, 2010. Steady heat transfer boundary layer solutions of polar fluid. Int. Rev. Mech. Eng., 4: 185-187.

  66. Ferdows, M., K. Kaino and C.H. Chen, 2010. Dufour, Soret and Viscous dissipation effects on heat and mass transfer in porous media with high porosities. Int. J. Applied Eng. Res., 5: 477-484.
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  67. Ferdows, M., K. Kaino and S. Sivasankaran, 2009. Free convection flow in an inclined porous surface. J. Porous Media, 12: 997-1003.
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  68. Ferdows, M., J.C. Crepeau and A. Postelnicu, 2009. Natural convection flow with wall temperature considering internal heat generation. Int. J. Heat Technol., 27: 107-110.

  69. Ferdows, M., I. Khairul Islam and M. Ota, 2009. Effects of suction/injection on steady MHD flow towards a stretching surface with internal heat generation and variable temperature. Int. J. Math. Comput., 2: 140-152.
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  70. Ferdows, M. and M. Ota, 2009. Unsteady heat transfer boundary layer solutions of polar fluid. Int. J. Math. Comput., 4: 111-123.
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  71. Ferdows, M. and C.H. Chen, 2009. Heat and mass transfer on MHD free convection from a vertical plate in a porous medium with Dufour and Soret effects. Int. J. Heat Technol., 27: 31-36.

  72. Bhuvaneswari, M., S. Sivasankaran and M. Ferdows, 2009. Lie group analysis of natural convection heat and mass transfer in an inclined surface with chemical reaction. Nonlinear Anal.: Hybrid Syst., 3: 536-542.
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  73. Ferdows, M., K. Kaino and J.C. Crepeau, 2008. Thermal radiation effects on natural convection flow past a semi-infinite porous plate in a porous media with internal heat generation. Int. J. Applied Mech. Eng., 13: 277-280.

  74. Ferdows, M., K. Kaino and J.C. Crepeau, 2008. MHD free convection and mass transfer flow in a porous media with simultaneous rotating fluid. Int. J. Dyn. Fluids, 4: 69-82.

  75. Ferdows, M., E. Tzirtzilakis, K. Kaino and C.H. Chen, 2008. Soret and Dufour effects on natural convection heat and mass transfer flow in porous medium considering internal heat generation. Int. J. Applied Math. Stat., 13: 36-48.

  76. Ferdows, M., K. Kaino and J.C. Crepeau, 2007. Natural convection of a magnetohydrodynamic flow past a semiinfinite vertical porous plate in a porous medium. JP J. Heat Mass Transfer, 1: 15-25.
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  77. Ferdows, M., K. Kaino and J.C. Crepeau, 2007. Natural convection of a magnetohydrodynamic flow past a semi-infinite vertical porous plate in a porous medium with internal heat generation. Int. J. Heat Technol., 25: 91-94.

  78. Ferdows, M., K. Kaino and J.C. Crepeau, 2007. Natural convection flow past a vertical porous plate with internal heat generation and constant heat flux. JP J. Heat Mass Transfer, 1: 297-301.
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  79. Alam, M.S., M.M. Rahman, M. Ferdows, K. Kaino, E. Mureithi and A. Postelnicu, 2007. Diffusion-thermo and thermal-diffusion effects on free convective heat and mass transfer flow in a porous medium with time dependent temperature and concentration. Int. J. Applied Eng. Res., 2: 81-96.

  80. Alam, M.M., M. Ota, M. Ferdows, M.N. Islamv, M. Wahiduzzaman and K. Yamamoto, 2007. Flow through a rotating helical pipe with a wide range of the Dean number. Arch. Mech., 59: 501-517.
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  81. Ferdows, M. and M. Ota, 2006. Density of CO2 hydrate by Monte Carlo simulation. Proc. Inst. Mech. Eng. Part C: J. Mech. Eng. Sci., 220: 691-696.
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  82. Alam, M.S., M.M. Rahman, M.A. Maleque and M. Ferdows, 2006. Dufour and Soret effects on steady MHD combined free-forced convective and mass transfer flow past a semi-infinite vertical plate. Thammasat Int. J. Sci. Technol., 11: 1-12.
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  83. Alam, M.S., M. Ferdows, M. Ota and M.A. Maleque, 2006. Dufour and Soret effects on steady free convection and mass transfer flow past a semi-infinite vertical porous plate in a porous medium. Int. J. Applied Mech. Eng., 11: 535-545.
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  84. Alam, M.M., M. Ota, M. Ferdows, M.N. Islam, M. Wahiduzzaman and K. Yamamoto, 2006. Trajectory of the fluid particle in a rotating helical pipe. Int. J. Dyn. Fluids, 2: 31-54.
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  85. Ota, M. and M. Ferdows, 2005. Monte Carlo studies on thermophysical property and structure of CO2 hydrate produced from mixed gas of CO2+He. J. Eng. Thermophys., 13: 113-128.

  86. Ota, M. and M. Ferdows, 2005. Monte Carlo approach to the structure and thermodynamic property of CO2 hydrate. JSME Int. J. Ser. B: Fluids Thermal Eng., 48: 802-809.
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  87. Ferdows, M., M. Ota, M.A. Sattar and M. Alam, 2005. Similarity solution for MHD flow through vertical porous plate with suction. J. Comput. Applied Mech., 6: 15-25.
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  88. Ferdows, M. and M. Ota, 2005. Molecular simulation study for CO2 clathrate hydrate. Chem. Eng. Technol., 28: 168-173.
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  89. Ferdows, M. and M. Ota, 2005. CO2 clathrate hydrate structure: A Monte Carlo approach. JAKU: Eng. Sci., 16: 131-146.
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  90. Ferdows, M. and M. Hossain, 2005. Flood frequency analysis at different rivers in Bangladesh: A comparison study on probability distribution functions. Int. J. Sci. Technol., 10: 53-62.
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  91. Jahan, R., M. Kabir, M.H. Khan, M. Nora, A. Bhuiyan and M. Ferdows, 2004. Factors influencing type of health services and duration of suffering from diseases in rural Bangladesh: A case study. Chiangmai Univ. J., 3: 253-258.
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  92. Ferdows, M., M.A. Sattar and M.N.A. Siddiki, 2004. Numerical approach on parameters of the thermal radiation interaction with convection in a boundary layer flow at a vertical plate with variable suction. Thammast Int. J. Sci. Technol., 9: 19-28.
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