Buoyancy Effect on MHD Slip Flow and Heat Transfer of a Nanofluid Flow over a Vertical Porous Plate

  • Fayyaz Hussain Department of Mathematics, National College of Business Administration & Economics, Lahore, Pakistan
  • Sohaib Abdal School of Mathematics, Northwest University, Xi’an, China
  • Zameer Abbas Department of Mathematics, National College of Business Administration & Economics, Lahore, Pakistan
  • Nasir Hussain Department of Mathematics, National College of Business Administration & Economics, Lahore, Pakistan
  • Muhammad Adnan Department of Applied Mathematics, Northwestern Polytechnical University, Xi’an, China
  • Bagh Ali School of Energy and power, Xi’an Jiaotong University,Xi’an, China
  • Rana Muhammad Zulqarnain School of Mathematics, Northwest University, Xi’an, China
  • Liaqat Ali School of Energy and power, Xi’an Jiaotong University,Xi’an, China
  • Saba Younas Department of Mathematics, National College of Business Administration & Economics, Lahore, Pakistan
DOI: https://doi.org/10.32350/sir.41.01
Keywords: MHD, mixed convection, nanofluid, suction/blowing, thermal slip, velocity slip

Abstract

Abstract Views: 471

This study investigated the boundary layer flow and heat transfer aspects of a nanofluid over a porous plate with thermal radiation.Using suitable similarity transformations, partial differential equations were converted into ordinary differential equations and then solved numerically with the help of the Runge-Kutta scheme. The effects of various parameters were analyzed such as Prandtl number Pr, Lewis number Le, Thermophoresis Nt, Mixed convection parameter λ, Brownianmotion Nb, Magnetic parameter M, and Suction/Blowing parameter S. The results were depicted with the help of graphs.

Copyright(c) The Authors

Downloads

Download data is not yet available.

References

Alawi A, Sidik CAN, Xian WH, Kean HT, Kazi NS.Thermal conductivity and viscosity models of metallic oxides nanofluids. Int J Heat Mass Transfer. 2018;116: 1314–1325.

Abbas N, Awan BM, Amer M, et al. Applications of nanofluids in photovoltaic thermal systems: a review of recent advances. Phys A. 2019;536: 122–513.

Ahmed N, Shah AN, Ahmad B, Shah SIS, Ulhaq S, Gorji RM. Ransient MHD convective flow of fractional nanofluid between vertical plates. J Appl Comput Mech. 2019;5(4): 592–602.

Akbar SN, Butt WA. Entropy generation analysis for metachronal beating of ciliated Cu-water nanofluid with magnetic field. Int J Exergy. 2016;19(1): 41–54.

Ahmadloo E, Azizi S. Prediction of thermal conductivity of various nanofluids using artificial neural network. Int Commun Heat Transfer. 2016;74: 69–75.

Arulprakasajothi M, Elangovan K, Chandrasekhar U, Suresh S. Performance study of conical strip inserts in tube heat exchanger using water based titanium oxide nanofluid. J Therm Sci. 2018;22(1): 477–485.

Choi JT, Jang PS, Jung SD, Lim MH, Byeon MY, Choi JI. Effect of the freeze-thaw on the suspension stability and thermal conductivity of eg/water-based al2o3nanofluids. J Nanomater. 2019; 2019: 8. doi: https://doi.org/10.1155/2019/2076341

Das KK, Islam N, Santra KA, Ganguly R. Experimental investigation ofthermophysical properties of Al2O3–water nanofluid. J Mol Liq. 2017;237: 304–312.

Devendiran KD, Amirtham AA. A review on preparation, characterization, properties and applications of nanofluids. Renewable Sustainable Energy Rev. 2016; 60:2140.

Esfe HM, Saedodin S, Sina N, Afrand M, Rostami S. Designing an artificial neural network to predict thermal conductivity and dynamic viscosity of ferromagnetic nanofluid. Int Commun Heat Mass Transfer. 2015;68: 50–57.

Haque MMKA, Kim T, Oh SG, et al. Synthesis of graphene/multi-walled carbon nanotube composite and its nanofluid preparation. Nanosci Nanotechnol Lett. 2016;8: 1–8.

Hayat T, Waqas M, Shehzad AS, Alsaedi A. Stretched flow of Carreau nanofluid with convective boundary condition. Pramana – J Phys. 2016;86(1): 3–17.

Kundan L, Mallick SS. Effect of time dependent morphological parameters of nanoclusters on perikinetic heat conduction and induced micro-convection mechanisms of oxidebased nanofluids. Exp Heat Transfer. 2018;31(3):251–274.

Mansour AM, Ahmed ES, Rashad MA. MHD natural convection in a square enclosure using nanofluid with the influence of thermal boundary conditions. J Appl Fluid Mech. 2016:9(5): 2515–2525.

Mohamad FNM, Hamzah WA, Hamid AK, Mamat R. Heat transfer performance of Tio2–SiO2 nanofluid in Water-Ethylene Glycol mixture. J Mech Eng. 2018;SI 5(1): 39–48.

Mahmood K, Sajid M, Ali N, Javed T. Heat transfer analysis in the time-dependent axisymmetric stagnation point flow over a lubricated surface. Therm Sci. 2018;22(6a): 2483–2492.

Nicolasa X, Cheniera E, Lauriata G. Thermal boundary conditions for convective heat transfer of dilute gases in slip ow regime. Int J Therm Sci. 2019;135: 298–301.

Prakash A, Satsangi S, Mittal S, Nigam B, Mahto KP, Swain B. Investigation on Al2O3 nanoparticles for nanofluid applications - a review. Mater Sci Eng. 2018; 377: 112–175.

Ramzan M, Bilal M, Kanwa S, Chung DJ. Effects of variable thermal conductivity and non-linear thermal radiation past aneyring Powell nanofluid flow with chemical reaction. Theor Phys. 2017;67(6): 723–731.

Rao SA, Prasad RV, Nagendra NV, Reddy BN, Beg AO. Non-similar computational solution for boundary layer flows of non-Newtonian fluid from an inclined plate with thermal slip. J Appl Fluid Mech. 2016;9(2): 795–807.

Saleem S, Rafiq H, Al-Qahtani A, El-Aziz AM, Malik YM, Animasaun LI. Magneto Jeffrey nanofluid bio convection over a rotating vertical cone due to gyrostatic microorganism. Math Probl Eng. 2019;2019: 11.

Thakur M, Gangacharyulu D, Singh G. Effect of temperature and multiwalled carbon nanotubes concentration on thermophysical properties of water base nanofluid. Int J Mech Prod Eng Res Dev (IJMPERD). 2017; 7: 4151–160.

Uddin JM, Bég AO, Aziz A, Ismail MIA. Group analysis of free convection flow of a magnetic nanofluid with chemical reaction. Math Probl Eng. 2015;2015: 11.

Uysal C, Korkmaz EM. Estimation of entropy generation for ag-mgo/water hybrid nanofluid flow through rectangular minichannel by using artificial neural network. J Polytech. 2019;22(1): 41–51.

Abdal S, Hussain S, Ahmad F, Ali B. Hydromagnetic stagnation point flow of micropolar fluids due to a porous stretching surface with radiation and viscous dissipation effects. Sci Int. 2015;27(5): 3965–3971.

Abdal S, Ali B, Younas S, Ali L, Mariam A. Thermo-diffusion and multislip effects on MHD mixed convection unsteady flow of micropolar nanofluid over a shrinking/stretching sheet with radiation in the presence of heat source. Symmetry. 2019;12(1): 49–65.

Ali L, Liu X, Ali B, Mujeed S, Abdal S. Finite element simulation of multi-slip effects on unsteady MHD bioconvective micropolar nanofluid flow over a sheet with solutaladthermal convective boundary conditions. Coatings. 2019;9(12): 842–862.

Ali L, Liu X, Ali B, Mujeed S, Abdal S. Finite element analysis of thermo-diffusion and multi-slip effects on MHD unsteady flow of casson nano-fluid over a shrinking/stretching sheet with radiation and heat source. Appl Sci. 2019;9(23): 5217–5237.

Younas S, Hussain S, Abdal S, Ahmad F, Habib D. Computational study for magneto hydrodynamics buoyancy flow vertical permeable plate with chemical diffusion and thermal radiation. Sci Int. 2018;30(3):193–197.

Published
2020-03-24
How to Cite
1.
Fayyaz Hussain, Sohaib Abdal, Zameer Abbas, Nasir Hussain, Muhammad Adnan, Bagh Ali, Rana Muhammad Zulqarnain, Liaqat Ali, Saba Younas. Buoyancy Effect on MHD Slip Flow and Heat Transfer of a Nanofluid Flow over a Vertical Porous Plate . Sci Inquiry Rev. [Internet]. 2020Mar.24 [cited 2024Jun.8];4(1):01-6. Available from: https://journals.umt.edu.pk/index.php/SIR/article/view/758
Issue
Vol 4 No 1 (2020): March
Section
Orignal Article

Copyright (c) 2020 Fayyaz Hussain, Sohaib Abdal, Zameer Abbas, Nasir Hussain, Muhammad Adnan, Bagh Ali, Rana Muhammad Zulqarnain, Liaqat Ali, Saba Younas

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.