CLC number: O35
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2019-03-11
Cited: 0
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Nor Ain Azeany Mohd Nasir, Anuar Ishak, Ioan Pop. Stagnation point flow and heat transfer past a permeable stretching/shrinking Riga plate with velocity slip and radiation effects[J]. Journal of Zhejiang University Science A, 2019, 20(4): 290-299.
@article{title="Stagnation point flow and heat transfer past a permeable stretching/shrinking Riga plate with velocity slip and radiation effects",
author="Nor Ain Azeany Mohd Nasir, Anuar Ishak, Ioan Pop",
journal="Journal of Zhejiang University Science A",
volume="20",
number="4",
pages="290-299",
year="2019",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A1800029"
}
%0 Journal Article
%T Stagnation point flow and heat transfer past a permeable stretching/shrinking Riga plate with velocity slip and radiation effects
%A Nor Ain Azeany Mohd Nasir
%A Anuar Ishak
%A Ioan Pop
%J Journal of Zhejiang University SCIENCE A
%V 20
%N 4
%P 290-299
%@ 1673-565X
%D 2019
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.A1800029
TY - JOUR
T1 - Stagnation point flow and heat transfer past a permeable stretching/shrinking Riga plate with velocity slip and radiation effects
A1 - Nor Ain Azeany Mohd Nasir
A1 - Anuar Ishak
A1 - Ioan Pop
J0 - Journal of Zhejiang University Science A
VL - 20
IS - 4
SP - 290
EP - 299
%@ 1673-565X
Y1 - 2019
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.A1800029
Abstract: This paper concerns the stagnation point flow and heat transfer of a viscous and incompressible fluid passing through a flat riga plate with the effects of velocity slip and radiation. An appropriate similarity transformation is chosen to reduce the governing partial differential equations to a system of ordinary differential equations. The numerical results are verified by comparison with existing results from the literature for a special case of the present study. The computed results are analyzed and given in the form of tables and graphs. The behaviors of the skin friction coefficient and the heat transfer rate for various physical parameters are analyzed and discussed. dual solutions exist for both stretching and shrinking cases. Stability analysis reveals that the solution with lower boundary layer thickness is stable while the other solution is unstable. It is also observed that for the stable solution, the skin friction coefficient and the local Nusselt number increase as the suction effect is increased. For the shrinking case, a solution exists only for a certain range of the shrinking strength and this range increases with increasing value of the suction effect.
Authors discussed stagnation point flow and heat transfer of a viscous and incompressible fluid passing through a flat Riga plate with the effects of velocity slip and radiation. An existing similarity transformation (for such type of model) is used to reduce the governing partial differential equations into ordinary differential equations. Both steady and unsteady cases have been investigated. Dual solutions have been discussed for both stretching and shrinking cases. A stability analysis has been carried out to deal with the limitation of dual solutions. The results are computed numerically, graphical results are explored in detail. Paper is written very well. The work presented in this article is new and original.
[1]Abd El-Aziz M, 2016. Dual solutions in hydromagnetic stagnation point flow and heat transfer towards a stretching/ shrinking sheet with non-uniform heat source/sink and variable surface heat flux. Journal of the Egyptian Mathematical Society, 24(3):479-486.
[2]Ahmad A, Asghar S, Afzal S, 2016. Flow of nanofluid past a Riga plate. Journal of Magnetism and Magnetic Materials, 402:44-48.
[3]Ahmed N, Khan U, Mohyud-Din ST, 2017a. Influence of nonlinear thermal radiation on the viscous flow through a deformable asymmetric porous channel: a numerical study. Journal of Molecular Liquids, 225:167-173.
[4]Ahmed N, Khan U, Mohyud-Din ST, 2017b. Influence of thermal radiation and viscous dissipation on squeezed flow of water between Riga plates saturated with carbon nanotubes. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 522:389-398.
[5]Ahmed N, Khan U, Mohyud-Din ST, et al., 2017c. Shape effects of nanoparticles on the Squeezed flow between two Riga Plates in the presence of thermal radiation. The European Physical Journal Plus, 132(7):321.
[6]Ahmed N, Khan U, Mohyud-Din ST, et al., 2018. A finite element investigation of the flow of a Newtonian fluid in dilating and squeezing porous channel under the influence of nonlinear thermal radiation. Neural Computing and Applications, 29(2):501-508.
[7]Asadullah M, Khan U, Ahmed N, et al., 2016. Analytical and numerical investigation of thermal radiation effects on flow of viscous incompressible fluid with stretchable convergent/divergent channels. Journal of Molecular Liquids, 224:768-775.
[8]Awaludin IS, Weidman PD, Ishak A, 2016. Stability analysis of stagnation-point flow over a stretching/shrinking sheet. AIP Advances, 6(4):045308.
[9]Ayub M, Abbas T, Bhatti MM, 2016. Inspiration of slip effects on electromagnetohydrodynamics (EMHD) nanofluid flow through a horizontal Riga plate. The European Physical Journal Plus, 131(6):193.
[10]Aziz A, Niedbalski N, 2011. Thermally developing microtube gas flow with axial conduction and viscous dissipation. International Journal of Thermal Sciences, 50(3):332-340.
[11]Bai Y, Liu XL, Zhang Y, et al., 2016. Stagnation-point heat and mass transfer of MHD Maxwell nanofluids over a stretching surface in the presence of thermophoresis. Journal of Molecular Liquids, 224:1172-1180.
[12]Chen S, Tian ZW, 2010. Simulation of thermal micro-flow using lattice Boltzmann method with Langmuir slip model. International Journal of Heat and Fluid Flow, 31(2):227-235.
[13]Chiam TC, 1994. Stagnation-point flow towards a stretching plate. Journal of the Physical Society of Japan, 63(6):2443-2444.
[14]Cortel R, 2008. Effects of viscous dissipation and radiation on the thermal boundary layer over a nonlinearly stretching sheet. Physics Letters A, 372(5):631-636.
[15]Farooq M, Khan MI, Waqas M, et al., 2016a. MHD stagnation point flow of viscoelastic nanofluid with non-linear radiation effects. Journal of Molecular Liquids, 221:1097-1103.
[16]Farooq M, Anjum A, Hayat T, et al., 2016b. Melting heat transfer in the flow over a variable thicked Riga plate with homogeneous-heterogeneous reactions. Journal of Molecular Liquids, 224:1341-1347.
[17]Hady FM, Ibrahim FS, Abdel-Gaied SM, et al., 2012. Radiation effect on viscous flow of a nanofluid and heat transfer over a nonlinearly stretching sheet. Nanoscale Research Letters, 7(1):229.
[18]Hayat T, Abbas T, Ayub M, et al., 2016. Flow of nanofluid due to convectively heated Riga plate with variable thickness. Journal of Molecular Liquids, 222:854-862.
[19]Hayat T, Khan M, Imtiaz M, et al., 2017. Squeezing flow past a Riga plate with chemical reaction and convective conditions. Journal of Molecular Liquids, 225:569-576.
[20]Hiemenz K, 1911. Die Grenzschicht an einem in den gleichformingen Flussigkeitsstrom einge-tauchten graden Kreiszylinder. Dingler’s Polytechnisches Journal, 326: 321-324 (in German).
[21]Howarth L, 1951. The boundary layer in three dimensional flow. Part II. The flow near a stagnation point. Philosophical Magazine, 42(7):1433-1440.
[22]Hsiao KL, 2016. Stagnation electrical MHD nanofluid mixed convection with slip boundary on a stretching sheet. Applied Thermal Engineering, 98:850-861.
[23]Hsiao KL, 2017a. Combined electrical MHD heat transfer thermal extrusion system using Maxwell fluid with radiative and viscous dissipation effects. Applied Thermal Engineering, 112:1281-1288.
[24]Hsiao KL, 2017b. Micropolar nanofluid flow with MHD and viscous dissipation effects towards a stretching sheet with multimedia feature. International Journal of Heat and Mass Transfer, 112:983-990.
[25]Hsiao KL, 2017c. To promote radiation electrical MHD activation energy thermal extrusion manufacturing system efficiency by using Carreau-nanofluid with parameters control method. Energy, 130:486-499.
[26]Iqbal Z, Mehmood Z, Azhar E, et al., 2017. Numerical investigation of nanofluidic transport of gyrotactic microorganisms submerged in water towards Riga plate. Journal of Molecular Liquids, 234:296-308.
[27]Jha BK, Aina B, 2015. Mathematical modelling and exact solution of steady fully developed mixed convection flow in a vertical micro-porous-annulus. Afrika Matematika, 26(7-8):1199-1213.
[28]Khadrawi AF, Al-Shyyab A, 2010. Slip flow and heat transfer in axially moving micro-concentric cylinders. International Communications in Heat and Mass Transfer, 37(8):1149-1152.
[29]Khan U, Ahmed N, Bin-Mohsen B, et al., 2017a. Nonlinear radiation effects on flow of nanofluid over a porous wedge in the presence of magnetic field. International Journal of Numerical Methods for Heat & Fluid Flow, 27(1):48-63.
[30]Khan U, Ahmed N, Mohyud-Din ST, et al., 2017b. Nonlinear radiation effects on MHD flow of nanofluid over a nonlinearly stretching/shrinking wedge. Neural Computing and Applications, 28(8):2041-2050.
[31]Khan U, Abbasi A, Ahmed N, et al., 2017c. Particle shape, thermal radiations, viscous dissipation and joule heating effects on flow of magneto-nanofluid in a rotating system. Engineering Computations, 34(8):2479-2498.
[32]Kumari M, Nath G, 1999. Development of flow and heat transfer of a viscous fluid in the stagnation-point region of a three-dimensional body with a magnetic field. Acta Mechanica, 135(1-2):1-12.
[33]Kuznetsov AV, Nield DA, 2010. Natural convective boundary-layer flow of a nanofluid past a vertical plate. International Journal of Thermal Sciences, 49(2):243-247.
[34]Magyari E, Pantokratoras A, 2011a. Aiding and opposing mixed convection flows over the Riga-plate. Communications in Nonlinear Science and Numerical Simulation, 16(8):3158-3167.
[35]Magyari E, Pantokratoras A, 2011b. Note on the effect of thermal radiation in the linearized Rosseland approximation on the heat transfer characteristics of various boundary layer flows. International Communications in Heat and Mass Transfer, 38(5):554-556.
[36]Mahapatra TR, Gupta AS, 2001. Magnetohydrodynamic stagnation-point flow towards a stretching sheet. Acta Mechanica, 152(1-4):191-196.
[37]Malvandi A, Ganji DD, 2014. Mixed convective heat transfer of water/alumina nanofluid inside a vertical microchannel. Powder Technology, 263:37-44.
[38]Nandy SK, Pop I, 2014. Effects of magnetic field and thermal radiation on stagnation flow and heat transfer of nanofluid over a shrinking surface. International Communications in Heat and Mass Transfer, 53:50-55.
[39]Nasir NAAM, Ishak A, Pop I, 2017. Stagnation-point flow and heat transfer past a permeable quadratically stretching/ shrinking sheet. Chinese Journal of Physics, 55(5):2081-2091.
[40]Nazar R, Amin N, Filip D, et al., 2004. Unsteady boundary layer flow in the region of the stagnation point on a stretching sheet. International Journal of Engineering Science, 42(11-12):1241-1253.
[41]Noghrehabadi A, Pourrajab R, Ghalambaz M, 2012. Effect of partial slip boundary condition on the flow and heat transfer of nanofluids past stretching sheet prescribed constant wall temperature. International Journal of Thermal Sciences, 54:253-261.
[42]Oyelakin IS, Mondal S, Sibanda P, 2016. Unsteady Casson nanofluid flow over a stretching sheet with thermal radiation, convective and slip boundary conditions. Alexandria Engineering Journal, 55(2):1025-1035.
[43]Pantokratoras A, Magyari E, 2009. EMHD free-convection boundary-layer flow from a Riga-plate. Journal of Engineering Mathematics, 64(3):303-315.
[44]Rosca AV, Rosca NC, Pop I, 2016. Numerical simulation of the stagnation point flow past a permeable stretching/ shrinking sheet with convective boundary condition and heat generation. International Journal of Numerical Methods for Heat & Fluid Flow, 26(1):348-364.
[45]Rosca NC, Pop I, 2013. Mixed convection stagnation point flow past a vertical flat plate with a second order slip: heat flux case. International Journal of Heat and Mass Transfer, 65:102-109.
[46]Sharma R, Ishak A, Pop I, 2014. Stability analysis of magnetohydrodynamic stagnation-point flow toward a stretching/ shrinking sheet. Computers & Fluids, 102:94-98.
[47]Torabi M, Peterson GP, 2016. Effects of velocity slip and temperature jump on the heat transfer and entropy generation in micro porous channels under magnetic field. International Journal of Heat and Mass Transfer, 102: 585-595.
[48]Weidman PD, Kubitschek DG, Davis AMJ, 2006. The effect of transpiration on self-similar boundary layer flow over moving surfaces. International Journal of Engineering Science, 44(11-12):730-737.
[49]Yacob NA, Ishak A, 2011. MHD flow of a micropolar fluid towards a vertical permeable plate with prescribed surface heat flux. Chemical Engineering Research and Design, 89(11):2291-2297.
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