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Neural Computing and Applications

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10-12-2016 | Original Article

A mathematical model of MHD nanofluid flow having gyrotactic microorganisms with thermal radiation and chemical reaction effects

Authors: M. M. Bhatti, S. R. Mishra, T. Abbas, M. M. Rashidi

Published in: Neural Computing and Applications | Issue 4/2018

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Abstract

In this article, we have examined three-dimensional unsteady MHD boundary layer flow of viscous nanofluid having gyrotactic microorganisms through a stretching porous cylinder. Simultaneous effects of nonlinear thermal radiation and chemical reaction are taken into account. Moreover, the effects of velocity slip and thermal slip are also considered. The governing flow problem is modelled by means of similarity transformation variables with their relevant boundary conditions. The obtained reduced highly nonlinear coupled ordinary differential equations are solved numerically by means of nonlinear shooting technique. The effects of all the governing parameters are discussed for velocity profile, temperature profile, nanoparticle concentration profile and motile microorganisms’ density function presented with the help of tables and graphs. The numerical comparison is also presented with the existing published results as a special case of our study. It is found that velocity of the fluid diminishes for large values of magnetic parameter and porosity parameter. Radiation effects show an increment in the temperature profile, whereas thermal slip parameter shows converse effect. Furthermore, it is also observed that chemical reaction parameter significantly enhances the nanoparticle concentration profile. The present study is also applicable in bio-nano-polymer process and in different industrial process.

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Thomas S, Yang W (eds) (2009) Advances in polymer processing: from macro-to nano-scales. Woodhead Publishing, Oxford

Bachok N, Ishak A (2010) Flow and heat transfer over a stretching cylinder with prescribed surface heat flux. Malays J Math Sci 4:159–169MATH

Stasiak J, Squires AM, Castelletto V, Hamley IW, Moggridge GD (2009) Effect of stretching on the structure of cylinder and sphere-forming styrene–isoprene–styrene block copolymers. Macromolecules 42:5256–5265CrossRef

Sakiadis BC (1961) Boundary layer behaviour on continuous solid surfaces: I. Boundary layer equations for two-dimensional and axisymmetric flow. AIChE J 7:26–28CrossRef

Crane LJ (1970) Flow past a stretching plate. Z Angew Math Phys 21(4):645–647. doi:10.1007/BF01587695 CrossRef

Datta BK, Roy P, Gupta AS (1985) Temperature field over a stretching sheet with uniform heat flux. Int J Heat Mass Trans 12:89–94CrossRef

Chen CK, Char MI (1988) Heat transfer of a continuous stretching surface with suction and blowing. J Math Anal Appl 135:568–580MathSciNetCrossRefMATH

Bhatti MM, Shahid A, Rashidi MM (2016) Numerical simulation of fluid flow over a shrinking porous sheet by successive linearization method. Alex Eng J 55:51–56CrossRef

Bhatti MM, Abbas T, Rashidi MM (2016) A New numerical simulation of MHD stagnation-point flow over a permeable stretching/shrinking sheet in porous media with heat transfer. Iran J Sci Technol Trans A Sci. doi:10.1007/s40995-016-0027-6

10.

Saidur R, Leong KY, Mohammad HA (2011) A review on applications and challenges of nanofluids. Renew sustain Energy Rev 15:1646–1668CrossRef

11.

Wong KV, De Leon O (2010) Applications of nanofluids: current and future. Adv Mech Eng 2:519659CrossRef

12.

Yu W, Xie H (2012) A review on nanofluids: preparation, stability mechanisms, and applications. J Nanomater 2012:1

13.

Raees A, Xu H, Liao SJ (2015) Unsteady mixed nano-bioconvection flow in a horizontal channel with its upper plate expanding or contracting. Int J Heat Mass Transf 86:174–182CrossRef

14.

Anoop KB, Sundararajan T, Das SK (2009) Effect of particle size on the convective heat transfer in nanofluid in the developing region. Int J Heat Mass Transf 52:2189–2195CrossRefMATH

15.

Pedley TJ (2010) Instability of uniform micro-organism suspensions revisited. J Fluid Mech 647:335–359MathSciNetCrossRefMATH

16.

Xu H, Pop I (2014) Mixed convection flow of a nanofluid over a stretching surface with uniform free stream in the presence of both nanoparticles and gyrotactic microorganisms. Int J Heat Mass Transf 75:610–623CrossRef

17.

Aziz A, Khan WA, Pop I (2012) Free convection boundary layer flow past a horizontal flat plate embedded in porous medium filled by nanofluid containing gyrotactic microorganisms. Int J Therm Sci 56:48–57CrossRef

18.

Tham L, Nazar R, Pop I (2013) Mixed convection flow over a solid sphere embedded in a porous medium filled by a nanofluid containing gyrotactic microorganisms. Int J Heat Mass Transf 62:647–660CrossRef

19.

Saranya S, Radha KV (2014) Review of nanobiopolymers for controlled drug delivery. Polym Plast Technol Eng 53:1636–1646CrossRef

20.

Oh JK, Lee DI, Park JM (2009) Biopolymer-based microgels/nanogels for drug delivery applications. Prog Polym Sci 34:1261–1282CrossRef

21.

Abo-Eldahab EM, Abd El-Aziz M (2000) Radiation effect on heat transfer in electrically conducting fluid at a stretching surface with uniform free stream. J Phys D Appl Phys 33:3180–3185CrossRef

22.

Cortell R (2008) Effects of viscous dissipation and radiation on the thermal boundary layer over a nonlinearly stretching sheet. Phys Lett A 372:631–636CrossRefMATH

23.

Cortell R (2006) Effects of viscous dissipation and work done by deformation on MHD flow and heat transfer of a viscoelastic fluid over a stretching sheet. Phys Lett A 357:298–305CrossRefMATH

24.

Bhatti MM, Abbas T, Rashidi MM, Ali MES (2016) Numerical simulation of entropy generation with thermal radiation on MHD carreau nanofluid towards a shrinking sheet. Entropy 18(6):200MathSciNetCrossRef

25.

Bhatti MM, Rashidi MM (2016) Effects of thermo-diffusion and thermal radiation on Williamson nanofluid over a porous shrinking/stretching sheet. J Mol Liq 221:567–573CrossRef

26.

Bhatti MM, Rashidi MM (2016) Entropy generation with nonlinear thermal radiation in MHD boundary layer flow over a permeable shrinking/stretching sheet: numerical solution. J Nanofluids 5:543–548CrossRef

27.

Anjalidevi SP, Kandasamy R (1999) Effects of chemical reaction, heat and mass transfer on laminar flow along a semi infinite horizontal plate. Heat Mass Transf 35:465–467CrossRef

28.

Hayat T, Muhammad T, Shehzad AS, Alsaedi A (2015) Similarity solution to threedimensional boundary layer flow of second grade nanofluid past a stretching surface with thermal radiation and heat source/sink. AIP Adv 5:017107CrossRef

29.

Abel MS, Siddheshwar PG, Mahesha N (2009) Effects of thermal buoyancy and variable thermal conductivity on the MHD flow and heat transfer in a power-law fluid past a vertical stretching sheet in the presence of a non-uniform heat source. Int J Non Linear Mech 44:1–12CrossRefMATH

30.

Sheikholeslami M, Rashidi MM (2015) Effect of space dependent magnetic field on free convection of Fe₃O₄–water nanofluid. J Taiwan Inst Chem Eng. doi:10.1016/jjtice.2015.03.035

31.

Sheikholeslami M (2014) Effect of spatially variable magnetic field on ferrofluid flow and heat transfer considering constant heat flux boundary condition. Eur Phys J Plus 2014:129–248

32.

Sheikholeslami M, Ganji DD, Rashidi MM (2015) Ferrofluid flow and heat transfer in a semi annulus enclosure in the presence of magnetic source considering thermal radiation. J Taiwan Inst Chem Eng 47:6–17CrossRef

33.

Ishak A, Nazar R, Pop I (2008) Magnetohydrodynamics flow and heat transfer due to a stretching cylinder. Energy Convers Manag 49:3265–3269CrossRefMATH

34.

Mukhopadhyay S (2013) MHD boundary layer slip flow along a stretching cylinder. Ain Shams Eng J 4:317–324CrossRef

35.

Ishak A (2010) Unsteady MHD flow and heat transfer over a stretching plate. J Appl Sci 10:2127–2131CrossRef

36.

Pop I, Na TY (1998) A note on MHD flow over a stretching permeable surface. Mech Res Commun 25:263–269MathSciNetCrossRefMATH

37.

Khan K, Abel MS, Sonth RM (2003) Visco-elastic MHD flow heat and mass transfer over a porous stretching sheet with dissipation of energy and stress work. Heat Mass Trans 40:47–57CrossRef

38.

Abed Mahdi R, Mohammed HA, Munisamy KM, Saeid NH (2015) Review of convection heat transfer and fluid flow in porous media with nanofluid. Renew Sust Energy Rev 41:715–734CrossRef

39.

Abed Mahdi R, Mohammed HA, Munisamy KM (2013) Improvement of convection heat transfer by using porous media and nanofluid: review. Int J Sci Res 2:34–47

40.

Das KS, Choi SU, Yu W, Pradep T (2007) Nanofluid: science and technology. Wiley, LondonCrossRef

41.

James M, Mureithi EW, Kuznetsov D (2014) Natural convection flow past an impermeable vertical plate embedded in nanofluid saturated porous medium with temperature dependent viscosity. Asian J Math Appl 2014:ama0165

42.

Ishak A, Nazar R, Pop I (2008) Magnetohydrodynamic (MHD) flow and heat transfer due to a stretching cylinder. Energy Convers Manag 49:3265–3269CrossRefMATH

43.

Wang CY (1988) Fluid flow due to a stretching cylinder. Phys Fluids 31:466–468CrossRef

44.

Basir MFM, Uddin MJ, Ismail AM, Bég OA (2016) Nanofluid slip flow over a stretching cylinder with Schmidt and Péclet number effects. AIP Adv 6:055316CrossRef

Title: A mathematical model of MHD nanofluid flow having gyrotactic microorganisms with thermal radiation and chemical reaction effects
Authors: M. M. Bhatti
S. R. Mishra
T. Abbas
M. M. Rashidi
Publication date: 10-12-2016
Publisher: Springer London
Published in: Neural Computing and Applications / Issue 4/2018
Print ISSN: 0941-0643
Electronic ISSN: 1433-3058
DOI: https://doi.org/10.1007/s00521-016-2768-8

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