International Scientific Journal


The computational investigations on mixed convection stagnation point flow of Jeffrey nanofluid over a stretched surface is presented herein. The sheet is placed vertical over which nanomaterials flowing upward direction. Arrhenius activation energy and binary chemical reaction are accounted. Non-linear radiative heat flux, MHD, viscous dissipation, heat source/sink, and Joule heating are considered. Initially the non-linear flow expressions are converted to ordinary one and then tackled for series solutions by homotopy analysis method. Consider flow problem are discussed for velocity, temperature and concentration through various flow variables. Furthermore, skin friction coefficient, Sherwood number, and heat transfer rate are computed graphically.
PAPER REVISED: 2018-07-20
PAPER ACCEPTED: 2018-07-22
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THERMAL SCIENCE YEAR 2020, VOLUME 24, ISSUE Issue 2, PAGES [1143 - 1155]
  1. Hayat, T., et al., Modeling and analyzing flow of third grade nanofluid due to rotating stretchable disk with chemical reaction and heat source, Physica B: Condensed Matter, 537, (2018), pp, 116-126
  2. Turkyilmazoglu, M., Mixed convection flow of magnetohydrodynamic micropolar fluid due to a porous heated/cooled deformable plate: Exact solutions, International Journal of Heat and Mass Transfer, 106 (2017), pp, 127-134
  3. Hayat, T., et al., Exploring magnetic dipole contribution on radiative flow of ferromagnetic Williamson fluid, Results in Physics, 8 (2018), pp, 545-551
  4. Kumar, R., et al., Radiative heat transfer study for flow of non-Newtonian nanofluid past a Riga plate with variable thickness, Journal of Molecular Liquids, 248 (2017), pp, 143-152
  5. Hayat, T., et al., Non-Darcy Forchheimer flow of ferromagnetic second grade fluid, Results in Physics, 7 (2017), pp, 3419-3424
  6. Thammanna, G. T., et al., Three dimensional MHD flow of couple stress Casson fluid past an unsteady stretching surface with chemical reaction, Results in Physics, 7 (2017), pp, 4104-4110
  7. Kumar, K. G., Effects of mass transfer on MHD three dimensional flow of a Prandtl liquid over a flat plate in the presence of chemical reaction, Results in Physics, 7 (2017), pp, 3465-3471
  8. Kumar, K. G., et al., Impact of Chemical Reaction on Marangoni Boundary Layer Flow of a Casson Nano Liquid in the Presence of Uniform Heat Source Sink, Diffusion Foundations, 11 (2017), pp, 22-32
  9. Abbasi, F. M., et al., Mixed convection flow of jeffrey nanofluid with thermal radiation and double stratification, Journal of Hydrodynamics, Ser. B, 28 (2016) 5, pp, 840-849
  10. Javed, M. F., et al., Axisymmetric flow of Casson fluid by a swirling cylinder, Results in Physics, 9 (2018), pp, 1250-1255.
  11. Khan, N. B., et al., Numerical investigation of vortex-induced vibration of an elastically mounted circular cylinder with One-degree of freedom at high Reynolds number using different turbulent models, Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment, (2018) doi: 10.1177/1475090217751992.
  12. Hayat, T., et al., Heat and mass transfer analysis in the stagnation region of Maxwell fluid with chemical reaction over a stretched surface, Journal of Thermal Science and Engineering Applications, 10 (2018), pp, 011002.
  13. Khan, N. B., et al., Numerical investigation of the vortex-induced vibration of an elastically mounted circular cylinder at high Reynolds number (Re = 10⁴) and low mass ratio using the RANS code, Plos One, 12 (2017) e0185832.
  14. Khan, N. B., et al., VIV study of an elastically mounted cylinder having low mass-damping ratio using RANS model, International Journal of Heat and Mass Transfer, 121 (2018), pp, 309-314.
  15. Shehzad, S. A., et al., Three-dimensional flow of Jeffery fluid with convective surface boundary conditions, International Journal of Heat and Mass Transfer, 55 (2012), pp, 3971-3976
  16. Turkyilmazoglu, M., Pop I., Exact analytical solutions for the flow and heat transfer near the stagnation point on a stretching/shrinking sheet in a Jeffrey fluid, International Journal of Heat and Mass Transfer, 57 (2013), pp, 82-88
  17. Khan, M., et al., Thermal and concentration diffusion in Jeffery nanofluid flow over an inclined stretching sheet: A generalized Fourier's and Fick's perspective, Journal of Molecular Liquids, 251 (2018), pp, 7-14
  18. Hayat, T., et al., Three-dimensional flow of a Jeffery fluid over a linearly stretching sheet, Communications in Nonlinear Science and Numerical Simulatio., 17 (2012), pp, 699-707
  19. Ojjela, O., Influence of thermophoresis and induced magnetic field on chemically reacting mixed convective flow of Jeffrey fluid between porous parallel plates, Journal of Molecular Liquids, 232 (2017), pp, 195-206
  20. Rudraswamy, N. G., et al., Combined Effect of Joule Heating and Viscous Dissipation on MHD Three Dimensional Flow of a Jeffrey Nanofluid, Journal of Nanofluids, 6 (2017) 2, pp, 300-310
  21. Kumar, K. G., et al., Influence of nonlinear thermal radiation and viscous dissipation on three-dimensional flow of Jeffrey nano fluid over a stretching sheet in the presence of Joule heating, Nonlinear Engineering, 6 (2017) 3, pp, 207-219
  22. Rudraswamy, N. G., et al., Soret and Dufour Effects in Three-Dimensional Flow of Jeffery Nanofluid in the Presence of Nonlinear Thermal Radiation, Journal of Nanoengineering and Nanomanufacturing,6 (2016) 4, pp, 278-287
  23. Choi, S. U. S., Enhancing thermal conductivity of fluids with nanoparticles developments and applications of non-Newtonian fluid flow, ASME FED, 66 (1995), pp, 99-105
  24. Buongiorno, J., Convective transfort in nanofluids, ASME Journal of Heat Transfer, 128 (2006), pp, 240-250
  25. Sheikholeslami, M., et al., Simulation of MHD CuO--water nanofluid flow and convective heat transfer considering Lorentz forces, Journal of Magnetism and Magnetic Materials, 369 (2014), pp, 69-80
  26. Farooq, M., et al., MHD stagnation point flow of viscoelastic nanofluid with non-linear radiation effects, Journal of Molecular Liquids, 221 (2016), pp, 1097-1103
  27. Abbasi, F. M., Doubly stratified mixed convection flow of Maxwell nanofluid with heat generation/absorption, Journal of Magnetism and Magnetic Materials, 404 (2016), pp, 159-165
  28. Hayat, T., et al., Simulation of ferromagnetic nanomaterial flow of Maxwell fluid, Results in Physics, 8 (2018), pp, 34-40
  29. Lin, Y., et al., MHD pseudo-plastic nanofluid unsteady flow and heat transfer in a finite thin film over stretching surface with internal heat generation, International Journal of Heat and Mass Transfer, 84 (2015), pp, 903-911
  30. Zeeshan, A., et al., Analysis of activation energy in Couette-Poiseuille flow of nanofluid in the presence of chemical reaction and convective boundary conditions, Results in Physics, 8 (2018), pp, 502-512
  31. Hayat, T., et al., Modeling chemically reactive flow of sutterby nanofluid by a rotating disk in Presence of heat generation/absorption, Communications in Theoretical Physics, 69 (2018), pp, 569-576.
  32. Hassan, M., et al., Convective heat transfer flow of nanofluid in a porous medium over wavy surface, Physics Letters A, (2018), (In press)
  33. Hayat, T., et al., Entropy generation in Darcy-Forchheimer bidirectional flow of water-based carbon nanotubes with convective boundary conditions, Journal of Molecular Liquids, 265 (2018), pp, 629-638
  34. Shehzad, N., Electroosmotic Flow of MHD Power Law Al2O3-PVC Nanofluid in a Horizontal Channel: Couette-Poiseuille Flow Model, Communications in Theoretical Physics, 69 (2018), pp, 655-666
  35. Ahmad, S., Entropy generation optimization and unsteady squeezing flow of viscous fluid with five different shapes of nanoparticles, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 554 (2018), pp, 197-210
  36. Hayat, T., et al., Investigation of second grade fluid through temperature dependent thermal conductivity and non-Fourier heat flux, Results in Physics, 9 (2018), pp. 871-878
  37. Hayat, T., et al., A frame work for heat generation/absorption and modified homogeneous--heterogeneous reaction in flow based on non-Darcy--Forchheimer medium, Nuclear Engineering and Technology, 50 (2018), pp, 389-395
  38. Hayat, T., et al., Magnetohydrodynamic flow of Burgers fluid with heat source and power law heat flux, Chinese Journal of Physics, 55 (2017), pp, 318--330
  39. Qayyum, S., et al., Magnetohydrodynamic (MHD) nonlinear convective flow of Jeffrey nanofluid over a nonlinear stretching surface with variable thickness and chemical reaction, International Journal of Mechanical Sciences, 134 (2017), pp, 306-314
  40. Hayat, T., et al., Nonlinear thermal radiation aspects in stagnation point flow of tangent hyperbolic nanofluid with double diffusive convection, Journal of Molecular Liquids, 223 (2016), pp, 969-978

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