Total No. of International Publications: 97 (As of Oct. 2023)

61. Impact of injection/suction and entropy generation of the porous open cavity with the hybrid nanofluid.
      P. Gokulavani, M. Muthtamilselvan,  Bahaaeldin Abdalla
      Journal of Thermal Analysis and Calorimetry, Article in Press (2021)

60. Impact of injection/suction and entropy generation of the porous open cavity with the hybrid nanofluid.
      P. Gokulavani, M. Muthtamilselvan,  Bahaaeldin Abdalla
     Journal of Thermal Analysis and Calorimetry, Article in Press (2021)

59. Activation energy and chemical reaction on Cu-TiO2/water hybrid nanofluid flow in an existence of nonlinear radiation. 
     S Suganya, M Muthtamilselvan, Ziyad Ali.
     Applied Nanoscience, 11, 933-949 (2021)

58. A magneto-bioconvective and thermal conductivity enhancement in nanofluid flow containing gyrotactic microorganism.
      Ziyad Ali, A. Renuka M. Muthtamilselvan
     Case Studies in Thermal Engineering, 23, 100809 (2021)

57. Numerical investigation of open cavities with parallel insulated baffles.
      P. Gokulavani, M. Muthtamilselvan, Fahad Al-Amri, Bahaaeldin Abdalla, D.H. Doh.
      International Journal of Heat and Technology, 38, 611-621 (2020) 

56.  An exact solution for unsteady free convection flow of chemically reacting Al2O3 - SiO2/water  hybrid nanofluid.
      S Suganya, M Muthtamilselvan, Fahad Al-Amri, Bahaaeldin Abdalla 
      Proc IMechE Part C: J Mechanical Engineering Science, Accepted and Article in Press (2020)

55. Filtration of radiating and reacting SWCNT-MWCNT/water hybrid flow with the significance of Darcy-Forchheimer porous medium. 
      S. Suganya, M. Muthtamilselvan, Fahad Al-Amri, Bahaaeldin Abdalla, Deog-Hee Doh.
      Arabian Journal for Science and Engineering, Accepted and Article in Press (2020)

54. Stagnation point flow of nanofluid containing micro- organisms.
      Fahad Al-Amri, M. Muthtamilselvan.
      Case Studies in Thermal Engineering, 21: 100656 (2020)

53. Influence of the Lorentz force on the ventilation cavity having a centrally placed heated baffle filled with the Cu − Al2O3 − H2O hybrid nanofluid . 
      Rui Du, P. Gokulavani, M. Muthtamilselvan, Fahad Al-Amri, Bahaaeldin Abdalla.
      International Communications in Heat and Mass Transfer, 116: 104676, 2020

52.Effects of orientation of the centrally placed heated baffle in an alternative configured ventilation cavity.
     P. Gokulavani, M. Muthtamilselvan, Qasem Al-Mdallal, D.H. Doh
     The European Physical Journal- Plus, 135:23 (2020)

51. MHD convection of nanofluid in porous medium influenced by slanted Lorentz force.
      S. Sureshkumar, S. Muthukumar, M. Muthtamilselvan, D.H. Doh, Eswari Prem
      The European Physical Journal- Special Topics, 229, 331,346 (2020)

50. Homogeneous and heterogeneous reactions in a nanofluid flow due to a rotating disk of variable thickness using HAM. 
      D.H. Doh, M. Muthtamilselvan, B. Swathene, E. Ramya,
     Mathematics and Computers in Simulation, 168, 90-110 (2020)

49. Entropy analysis and nanofluid past a double stretchable spinning disk using Homotopy Analysis Method.
      A. Renuka M. Muthtamilselvan, D.H. Doh, C.R. Cho. 
     Mathematics and Computers in Simulation, 171, 152-169 (2020)

48. Cattaneo-Christov heat flux model for inclined MHD micropolar fluid flow past a  non- linearly stretchable  rotating disk. 
      D.H. Doh, G.R. Cho, E. Ramya, M. Muthtamilselvan.
     Case Studies in Thermal Engineering, 14, 100496 (2019 )

47. Effects of homogeneous- heterogeneous reactions in flow of nanofluid between two stretchable  rotating disks.
      A. Renuka M. Muthtamilselvan, D.H. Doh, G.R. Cho
      The European Physical Journal- Special Topics, 228, 2661-2676 (2019 )

46. Combined MHD convection and thermal radiation of nanofluid in a lid-driven porous enclosure with irregular thermal source on vertical sidewalls.
      S. Muthukumar, S. Sureshkumar, Ali J. Chamkha, M. Muthtamilselvan, Eswari Prem.
      Journal of Thermal Analysis and Calorimetry, 138, 583-596 (2019 )

45. Impact of magnetic field on convective flow of a micropolar fluid with two parallel heat sources.
      K Periyadurai, M. Muthtamilselvan, D.H. Doh. 
      Journal of Applied and  Computational Mechanics, 5, 652-666 (2019 )

44. A comparative study of viscosity models in nanofluid flow induced by tworotating disks with homogeneous-heterogeneousreaction. 
      A. Renuka, M. Muthtamilselvan, D.H. Doh.
     Journal of Nanofluids, 8, 1496-1505 (2019 )

43. Stagnation point flow of dusty Casson fluid with thermal radiation and buoyancy effects.
      M. Muthtamilselvan .
      Journal of Applied Analysis and Computation, 9, 615-627 (2019 )

42. Heat transfer analysis of a Williamson micropolar nanofluid with different flow controls.
      M. Muthtamilselvan, E. Ramya, D.H. Doh 
      J. Mechanics, 35, 381-394 (2019 )

41. Inclined Lorentz force effects on 3D micropolar fluid flow due to a stretchable rotating disks with higher order chemical reaction .
      M. Muthtamilselvan, E. Ramya, D.H. Doh.
      Proc. Ins. Mech. Engg. J. of Mech. Engineering Science, 233, 223-235 (2019)

40. Nanofluid flow and heat simultaneously induced by two stretchable rotating disks using Buongiorno’s model.
      M. Muthtamilselvan, A. Renuka
      Multidiscipline Modeling in Materials and Structures, 15, 1115-1128, (2018)

39. Effect of mutually orthogonal heated plates on buoyancy convection flow of micropolar fluid in a cavity.
      M. Muthtamilselvan, K Periyadurai, D.H. Doh. 
      Int. Journal of Numerical Methods for Heat and Fluid Flow, 28, 2231-2251 (2018)

38. Effects of thermal radiation on a 3D Sisko fluid over a porous medium using Cattaneo-Christov heat flux model. 
      Deog-Hee Doh, M. Muthtamilselvan, E. Ramya, P. Revathi 
      Communications in Theoretical Physics, 70, 230-238 (2018)

37. Numerical and analytical comparisons of slanted Lorentz forces on thermal radiation flow of a micropolar fluid. 
      E. Ramya, M.Muthtamilselvan, D.H. Doh, G.R. Cho
      Thermal Science, 23, 913-928 (2019)

36. Internal heat generation of a dusty fluid through porous media over a stretching sheet. 
      M.Muthtamilselvan, P. Gokulavani, E. Ramya, D.H. Doh. 
      Journal of Porous Media, 21, 845-863  (2018)

35. Convective heat transfer in a porous enclosure saturated by nanofluid with different heat sources.
      M. Muthtamilselvan S. Sureshkumar
      Nonlinear Engineering, 7, 1-16 (2018) 

34. A tilted orentz force effect on porous media filled with nanofluid .
      M. Muthtamilselvan, S. Sureshkumar.
      J. Theoretical and Applied Mechanics, 48, 50-71 (2018)

33. Absorbing/emitting radiation and slanted hydromagnetic effects  on micropolar liquid containing gyrostatic microorganisms .
      E. Ramya, M.Muthtamilselvan, D.H. Doh,
      Applied  Mathematics and Computation, 324, 69-81 (2018)

32. Impact of heated plate on double-diffusive natural convection of micropolar fluid in a cavity with Soret and Dufour effects. 
      M. Muthtamilselvan, K Periyadurai, D.H. Doh.
      Advanced Powder Technology, 29,66-77 (2018)

31.Coupled free and forced convection heat transfer in a porous enclosure saturated by nanofluid with irregular temperature distributions on sidewalls.
     M. Muthtamilselvan  S.Sureshkumar, D.H. Doh.
     International Journal of Chemical Reactor Engineering, 15, 20170151 (2017)

30. Convection of micropolar fluid in a square cavity with an inside heater.
     M. Muthtamilselvan, K Periyadurai, D.H. Doh.
    Journal of Thermophysics and Heat Transfer, 31, 817-831 (2017)

29. Heat transfer in a liquid film over an unsteady porous stretching sheet with different boundary conditions.
     M. Muthtamilselvan, E. Ramya. 
     Australian Journal of Mech. Engg., 15, 187-197 (2017)

28. Thermophoretic particle deposition on magnetohydrodynamic flow of micropolar fluid due to a rotating disk.
     D.H. Doh, M. Muthtamilselvan.
     International Journal of Mechanical Sciences, 130, 350–359 (2017)

27. Effect of uniform and nonuniform heat source on natural convective flow of micropolar fluid.
      M. Muthtamilselvan, K Periyadurai, D.H. Doh. 
      International Journal of Heat and Mass Transfer, 115, 19-34 (2017)

26. Convective heat transfer in a nanofluid-saturated porous cavity with the effects of aspect ratios and thermal radiation. 
      M. Muthtamilselvan S. Sureshkumar.
      Physics and Chemistry   of Liquids, 55, 617-636 (2017)

25. Effect of heat generation on transient flow of micropolar fluid between porous vertical channel.
      M. Muthtamilselvan, D. Prakash, D.H. Doh.
      Thermophysics & Aeromechanics, 24, 275-284 (2017)

24. Impact of aspect ratio on a nanofluid-saturated porous enclosure .
      M. Muthtamilselvan S. Sureshkumar.
      Mechanics and Industry, 18, 501 (2017)

23.Transient heat and mass  transfer of micropolar fluid between porous vertical channel with boundary conditions of third kind. 
     D.H. Doh, M. Muthtamilselvan D. Prakash.
     Int. J. of Nonlinear Sciences and Numerical Simulation, 17, 231-242 (2016 )

22. Influence of inclined Lorentz force on micropolar fluids in a square cavity with uniform and nonuniform heated thin plate .
      K Periyadurai, M. Muthtamilselvan, D.H. Doh.
     Journal of Magnetism and Magnetic Materials, 420, 343-355 (2016)

21.  Aspect ratio effects on natural convection in a water saturated porous cavity near its density maximum.
       D.H. Doh, M. Muthtamilselvan.  
       J. Engg. Thermophysics, 25,401-410 (2016)

20. A slanted porous enclosure filled with Cu-water nanofluid.
     S. Sureshkumar, M. Muthtamilselvan.
     European Physical Journal – Plus, 131, 95(1-19), (2016).

19. Unsteady MHD non-Darcian flow over a vertical stretching plate embedded in a porous medium with thermal non- equilibrium model. 
      M. Muthtamilselvan, D. Prakash, Xiao- Dong       
      Niu. Advances in Applied Mathematics & Mechanics, 8, 52-6 (2016)

18. Unsteady hydromagnetic slip flow and heat transfer of nanofluid over a moving surface with prescribed heat and mass fluxes. 
      M. Muthtamilselvan, D. Prakash.
      Proc. Ins. Mech. Engg. J. of Mech. Engineering Science, 299, 703-715 (2015)

17. Numerical investigation on mixed convection in a cavity filled with nanofluids.
      M. Muthtamilselvan .
      J. of Int. Academy of Physical Sciences, 18, 101-107 (2014)

16. Effect of radiation on transient flow of micropolar fluid between porous vertical channel with boundary conditions of the third kind. 
      D. Prakash, M. Muthtamilselvan.
      Ain Shams Engineering Journal, 5, 1277-1286 (2014)

15 .Effect of thermal non- equilibrium on transient hydromagnetic flow over a moving surface in a nanofluid saturated porous media. 
      M. Muthtamilselvan, D. Prakash, D.H. Doh.
      Journal of Mechanical Science and Technology, 28, 3709-3718 (2014)

14. Mixed convection of heat generating nanofluid in a lid-driven cavity with uniform and non-uniform heating of bottom wall .
      M. Muthtamilselvan D.H. Doh,
      Applied Mathematical Modelling, 38, 3164-3174 (2014)

13. Effect of non-uniform heat generation on unsteady MHD non-Darcian flow over a vertical stretching surface with variable properties.
      M. Muthtamilselvan, D. Prakash, D.H. Doh.
      Journal of Applied Fluid Mechanics, 7, 329-339 (2014)

12. Effect of non-uniform heat generation on unsteady MHD flow over a vertical stretching surface with variable thermal conductivity . 
      M. Muthtamilselvan, D. Prakash, D.H. Doh.
      J. Mechanics, 30, 199-208 (2014)

11 .Unsteady MHD non-Darcian flow over a vertical stretching plate embedded in a porous medium with non-uniform heat generation. 
     D. Prakash, M. Muthtamilselvan, D.H. Doh.
     Applied Mathematics & Computation, 236, 480-492 (2014)

10. Magnetic field effect on mixed convection in a lid-driven square cavity filled with nanofluid .
      M. Muthtamilselvan, D.H. Doh
      J. of Mechanical Science and Technology, 28, 137-143 (2014)

9. Effect of heat generation on forced convection through a porous saturated duct.
    D. Prakash, M. Muthtamilselvan, D.H. Doh,
    Transport in Porous Media, 95, 377-388 (2012)

8. Double diffusive convection in a porous cavity near its density maximum.
    M. Muthtamilselvan and Manab Kumar Das.
    Journal of Porous Media, 15, 765-774 (2012)

7. Mixed convection in a lid-driven square cavity filled with nanofluids.
    M. Muthtamilselvan and R. Rakkiyappan 
    Nanoscience and Technology: An International Journal, 2, 275-294 (2011)

6. Transient buoyancy-driven convection of water saturated porous cavity near its density maximum.
    M. Muthtamilselvan .
    Inter. J. Comp. Methods in Eng. Science & Mechanics, 12, 270–277 (2011)

5. Mixed convection in a lid-driven cavity utilizing nanofluids .
    M. Muthtamilselvan .
    CFD letters, 2, 163-175 (2010).

4. Hydromagnetic mixed convection in a two-sided lid- driven porous enclosure.
    M. Muthtamilselvan, J. Lee and P. Kandaswamy
    Int. J. of Fluid Mechanics Research, 37, 406-423 (2010)

3. Convection in a lid-driven heat- generating porous cavity with alternative thermal boundary  conditions. 
    M. Muthtamilselvan, Manab Kumar Das and P. Kandaswamy .
    Transport in Porous Media, 82, 337-346 (2010).

2.Heat transfer enhancement of copper-water nanofluids in a lid- driven cavity,
   M. Muthtamilselvan, P.  Kandaswamy and J. Lee,
   Comm. In Nonlinear science & Numerical Simulation, 15, 1501-1510 (2010).

1. Prandtl number effects on mixed convection in a lid-driven porous cavity,
    P. Kandaswamy, M. Muthtamilselvan and J. Lee,
    Journal of Porous Media, 11, 791-801 (2008)

Ongoing

Sl No.   Name of the candidate    Supervisor/Co-Supervisor    Title of the Thesis      Year 

1. S. SRIDHAR

2. V. NAVANEETHAKRISHNAN

3. Y. M. GIFTEENA HINGIS

4. P.M. RENUPRIYA       

Completed

Sl No.   Name of the candidate    Supervisor/Co-Supervisor    Title of the Thesis      Year  

1.  D. Prakash, Transient convective transport phenomena of nanofluid saturated porous media,  2014
2. S. Sureshkumar, Numerical study on mixed convection in a nanofluid-saturated porous cavity, 2017
3. K. Periyadurai, Natural convection of micropolar fluid in a square cavity in the presence of heat source, 2018

4. E. Ramya , Inclined Lorentz force on transient heat and mass transfer flow of micropolar fluid, 2018

5. A. Renuka,  A study of nanofluid flow of heat and mass transfer in a rotating system, 2019

6. P. Gokulavani, Convection in open cavity with heated baffles, 2020

7. S. Suganya, Radiating and rotating flow of various hybrid nanofluids over a stretching sheet, 2021

8. B. Kanimozhi, Combined buoyancy and Marangoni convection in a cylindrical porous annulus filled with hybrid nanofluid, 2022

9. R. Surendar, Hyper Chaos stabilization and synchronization of Darcy-Brinkman model for closed-loop control, 2023