PLoS ONEplosplosonePLOS ONE1932-6203Public Library of ScienceSan Francisco, CA USAPONE-D-16-3924810.1371/journal.pone.0170790Research ArticlePhysical sciencesPhysicsClassical mechanicsContinuum mechanicsFluid mechanicsFluid dynamicsFluid flowPhysical sciencesChemistryChemical reactionsEngineering and technologyPhysical sciencesPhysicsStates of matterFluidsPeople and placesPopulation groupingsProfessionsEngineersPhysical sciencesPhysicsClassical mechanicsMotionVelocityPhysical sciencesPhysicsCondensed matter physicsMagnetismMagnetic fieldsPhysical sciencesPhysicsClassical mechanicsContinuum mechanicsFluid mechanicsFluid dynamicsBrownian motionPhysical sciencesMathematicsProbability theoryStochastic processesBrownian motionRadiative Flow of Powell-Eyring Magneto-Nanofluid over a Stretching Cylinder with Chemical Reaction and Double Stratification near a Stagnation PointRadiative Flow of Powell-Eyring Magneto-NanofluidRamzanMuhammad1*BilalMuhammad2ChungJae Dong3Department of Computer Science, Bahria University, Islamabad Campus, Islamabad, 44000, PakistanDepartment of Mathematics, Faculty of Computing, Capital University of Science and Technology, Islamabad, PakistanDepartment of Mechanical Engineering, Sejong University, Seoul 143-747, KoreaNoreenSaimaEditorCOMSATS Institute of Information Technology, PAKISTAN
The authors have declared that no competing interests exist.
Conceptualization: MR MB JDC.
Data curation: MR MB JDC.
Formal analysis: MR MB JDC.
Funding acquisition: MR MB JDC.
Investigation: MR MB JDC.
Methodology: MR MB JDC.
Project administration: MR MB JDC.
Resources: MR MB JDC.
Software: MR MB JDC.
Supervision: MR MB JDC.
Validation: MR MB JDC.
Visualization: MR MB JDC.
Writing – original draft: MR MB JDC.
Writing – review & editing: MR MB JDC.
* E-mail: mramzan@bahria.edu.pk20172712017121e01707902310201611220162017Ramzan et alThis is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
This exploration addresses MHD stagnation point Powell Eyring nanofluid flow with double stratification. The effects of thermal radiation and chemical reaction are added in temperature and nanoparticle concentration fields respectively. Furthermore, appropriate transformations are betrothed to obtain nonlinear differential equations from the system of partial differential equations and an analytical solution of system of coupled differential equations is obtained by means of the renowned Homotopy Analysis method. Through graphical illustrations, momentum, energy and concentration distributions are conversed for different prominent parameters. Comparison in limiting case is also part of present study to validate the obtained results. It is witnessed that nanoparticle concentration is diminishing function of chemical reaction parameter. Moreover, mounting values of thermal and solutal stratification lowers the temperature and concentration fields respectively.
World Class 300 ProjectS2367878ChungJae DongThis work was supported by the World Class 300 Project (No. S2367878) of the SMBA (Korea).Data AvailabilityAll relevant data are within the paper. There are no supporting files to upload.1 Introduction
Interest of scientists and researchers towards non-Newtonian fluids has immensely increased during the last few decades due to extensive role of these fluids in industrial and engineering applications. Examples of non-Newtonian fluids may include sugar solution, soaps, emulsions, shampoos, apple sauce, paints, cheese, muds, different cosmetic products, asphalt and ice cream etc. Since many non-Newtonian fluids with numerous characteristics are present in nature, subsequently different mathematical models are proposed to represent these fluids. The equations of different non-Newtonian fluid models are more complex and challenging in comparison to Navier-Stokes equations. That is why mathematical modelling and solutions of these fluids’ equations are of great importance. The development in mathematical modelling of non-Newtonian fluids is of great interest even today [1–6]. Eyring Powell’s model has a key role in many chemical engineering processes and has advantages over other non-Newtonian fluid models due its simplicity and ease in computations. This fluid model is obtained from Kinetic theory of liquids instead of empirical equation. Moreover, for high and low shear stresses, it decorously converts to Newtonian fluids [7]. A reasonable number of communications can be quoted highlighting Eyring–Powell fluid model in the existing literature. Akbar et al. [8] examined Eyring Powell magneto fluid flow numerically past a stretching sheet using finite difference method. Hayat et al. [9] discussed Eyring Powell fluid flow past a stretched cylinder in attendance of magneto hydrodynamic and Newtonian heating. Hayat et al. [10] investigated mixed convective stagnation point Powell Eyring fluid flow with the impact of heat generation/absorption, thermal radiation and Newtonian heating. Hayat et al. [11] studied mixed convective Eyring Powell flow with effects of Soret and Dufour. The whole scenario is deliberated in attendance of convective heat and mass boundary conditions over an exponential stretched surface. Khan et al. [12] presented numerical and analytical solution of MHD Powell Eyring fluid flow with effects of joule heating, thermophoresis and chemical reaction.
The problem of low thermal conductivity of fluids like ethylene glycol, engine oil or water is solved by the introduction of nanofluids. Excellent heat transfer features of Nanofluids as compared to ordinary base fluids have made them more beneficial to many engineering and technological processes. Applications of nanofluids include heat exchangers, cancer therapy, thermal engineering, bio medicine and thermal engineering etc. Furthermore, in physics, medicine and engineering, abundant applications related to magnetic field may be found. Magnetic field with electrically conducting fluid has many applications, e.g., boundary layer control, pumps, bearings and MHD generators. Flow behavior highly depends on intensity of applied magnetic field and orientation of fluid molecules. Moreover, suspended particles of the fluid are rearranged by the applied magnetic field. This will ultimately change the concentration of the fluid with heat transfer characteristics. A fluid possessing characteristics of liquid and magnetic properties is known as magnetic nanofluid. Abundant applications of magnetic nanofluids, e. g., optical switches, nonlinear optical materials, magneto-optical wavelength filters and optical modulators etc. can be cited in this regard. All such interesting applications have motivated scientists and researchers to look for more avenues in the field of nanofluid flows and magnetic properties [13–20].
Many researchers are attracted to Stratification because of its important role in heat and mass transfer. Stratification occurs with fluids having varied densities and in flow fields with concentration variances and differences in temperature. Practically, it is imperative to examine the impact of double stratification whenever heat and mass transfer arise collectively. In the case of lakes and ponds, stratification is imperative to keep balance in the ratio of hydrogen and oxygen so that the growth rate of species is not disturbed. Moreover, in Solar engineering too, stratification plays a vital role in obtaining enhanced energy efficiency. Many researches have been conducted in this area. To name a few, Hayat et al. [21] examined series solution of time dependent nanofluid flow with viscous dissipation, double stratification and thermal radiation effects. Abbasi et al. [22] studied Maxwell nanofluid flow with effects of mixed convection, double stratification and magnetohydrodynamic. Hayat et al. [23] explored Jeffrey fluid flow under the influence of double stratification, heat generation/absorption and mixed convection past an inclined stretched cylinder. Hayat et al. [24] found series solution of Oldroyd-B fluid flow with double stratification and chemical reaction. Kaladhar et al. [25] investigated flow of couple stress fluid with mixed convection and double stratification using Keller box method.
Motivation from the above discussion, it is of paramount interest in this article to inspect the impact of double stratification, thermal radiation and magnetohydrodynamic on Powell-Eyring nanofluid flow past a stretched cylinder. None of the above quoted references simultaneously analyzed all such effects even in viscous fluid past a stretching cylinder near a stagnation point. Homotopy Analysis method [26–30] is engaged in order to find the analytical solution of the problem.
2 Mathematical formulation
We assume a situation in which Eyring Powell nanofluid flows past a stretching cylinder with impact of double stratification, thermal radiation and magnetohydrodynamic. This study also considers chemical reaction near a stagnation point. Moreover, cylindrical coordinates with z–axis are along the stretched cylinder whereas r–axis upright to it as shown in Fig 1 Ref. [31]. In an Eyring Powell fluid [32], we have
τij=μ∂wi∂zj+1βsinh-11λ∂wi∂zj
10.1371/journal.pone.0170790.g001
Flow diagram.
The equations representing this assumed system are given by
∂ru∂r+∂rw∂z=0,u∂w∂r+w∂w∂z=wedwedz+ν∂2w∂r2+1r∂w∂r+1ρβC1∂2w∂r2+1r∂w∂r-16ρβC131r∂w∂r3+3∂w∂r2∂2w∂r2-σBo2w-weρ,u∂T∂r+w∂T∂z=kρcp∂2T∂r2+1r∂T∂r-1ρCpr∂∂rrqrτDB∂T∂r∂C∂r+DTT∞∂T∂r2,u∂C∂r+w∂C∂z=DB1r∂∂rr∂C∂r+DTT∞1r∂∂rr∂T∂r-RrC-C∞,
with the boundary conditions
w=U0zl,u=0,T=Tw=T0+azl,C=Cw=C0+czlatr=R,w→we=V0zl,T→T∞=T0+bzl,C→C∞=C0+dzlasr→∞,
where u, w are velocity components in r and z directions respectively. Moreover, β and c, b and d, U0, l, ν, ρ, cp, k, T, T∞, we, DB and DT are fluid parameters, dimensionless constants, reference velocity, characteristic length, kinematic viscosity, density, specific heat, thermal conductivity, fluid temperature, ambient temperature, stretching velocity, Brownian diffusion coefficient and thermophoretic diffusion coefficient respectively.
Here, qr is Rosseland radiative heat flux and is given by
qr=-4σ*3k*∂T4∂z,
using value of qr in Eq (4), we get
u∂T∂r+w∂T∂z=kρcp∂2T∂r2+1r∂T∂r+1ρCpr4σ*3k*∂∂rr∂T4∂rτDB∂T∂r∂C∂r+DTT∞∂T∂r2,
Using the transformations of the form [33]
η=U0νlr2-R22R,ψ=νU0lRzfη,ϕη=C-C∞Cw-C∞w=U0zlf′η,u=-νU0lRrfη,θη=T-T∞Tw-T∞.
Requirement of Eq (2), is automatically fulfilled, however, Eqs (3), (5), (6) and (8) take the form given below
(1+2γη)(1+M)f‴+ff″−(f′)2+2γ(1+M)f″−43(1+2γη)Mγλf′′3−(1+2γη)2λMf′′2f‴−Ha2(f′−P0)+P02=0,(1+2γη)(1+43Rd)θ′′+2γ(1+43Rd)θ′+Pr(fθ′−f′θ−f′e)+PrNb(1+2γη)(θ′ϕ′+NtNbθ′2)=0,(1+2γη)ϕ′′+NtNbθ′′+2γϕ′+NtNbθ′+PrLe[fϕ′-f′ϕ-f′j]-Q0ϕ=0,f(0)=0,f′(0)=1,θ0=1-e,ϕ(0)=1-j,f′(∞)→P0,θ∞→0,ϕ(∞)→0.
Here, γ, M, and λ, Le, Pr, Ha, Q0, Nb, P0 and Nt are curvature parameter, fluid parameters, Lewis number, Prandtl number, Hartmann number, chemical reaction parameter, Brownian motion, velocity ratio and thermophoresis parameter respectively and are given by followings:
γ=νlU0R212,Pr=μcpk,Le=αDB,Ha=σBo2lρU0,M=1μβC1,λ=U03z22l3C12ν,P0=V0U0,Rd=4σ*T∞3kk*,e=ba,Nb=τDBCW-C∞υ,Nt=τDTTW-T∞υT∞,j=dc,Q0=RrlU0.
The relations of Skin friction, local Nusselt and Sherwood numbers are as follows:
Cf=τrzρwe2,Nu=zqwk(Tw-T∞),Sh=zjwk(Cw-C∞),τw=μ+1βc∂w∂r-16βC13∂w∂r3r=R,qw=-k∂T∂rr=R+qrr=R,jw=-∂C∂rr=R,
and in non dimensional form
CfRez1/2=1+Mf′′0-λ3Mf′′30,NuRe-1/2=-1+43Rdθ′0,ShRe-1/2=-ϕ′0,
where Rez = wez/ν is the Reynolds number.
3 Homotopic solutions
Homotopy analysis method necessitates initial guesstimates (f0, θ0, ϕ0) with auxiliary linear operators (Lf,Lθ,Lϕ) in the forms
f0η=P0η+1-P01-exp-η,θ0η=1-eexp-η,ϕ0η=1-jexp-η,Lfη=d3fdη3-dfdη,Lθη=d2θdη2-θ,Lϕη=d2ϕdη2-ϕ.
The auxiliary linear operators have the following properties
LfA1+A2exp(η)+A3exp(-η)=0,LθA4exp(η)+A5exp(-η)=0,LϕA6exp(η)+A7exp(-η)=0,
where Ai (i = 1 − 7) are the arbitrary constants. Through boundary conditions, the values of these constants are given by the equations
A2=A4=A6=0,A3=∂fm⋆η∂ηη=0,A1=-A3-fm⋆0,A5=-θm*0,A7=-ϕm*0.
3.1 Convergence analysis
HAM provides us with an opening to comfortably regulate and control the series solutions’ convergence. The selection of auxiliary parameters, ℏf, ℏθ and ℏϕ are central in regulating the convergence of desired solutions. To select suitable values of these auxiliary parameters, ℏ–curves are drawn to 14th order of estimates. Fig 2 depicts the endurable values of these parameters −1.6 ≤ ℏf ≤ −0.3, −1.1 ≤ ℏθ ≤ −0.3 and −1.3 ≤ ℏϕ ≤ −0.4. To validate our results obtained in Fig 2, numerical approximations to 25th order of estimates as given in Table 1, are also calculated and found in good agreement.
10.1371/journal.pone.0170790.g002
ℏ curves of f″(0), θ′(0), ϕ′(0).
10.1371/journal.pone.0170790.t001
Convergence of series solutions for different order of approximations when, M = 0.2, γ = 0.3, Ha = 0.2, P0 = 0.2, Q0 = 0.2, Rd = 0.3, λ = 0.2, J = 0.3, e = 0.3, Nt = 0.4, Nb = 0.6, Le = 1.0, and Pr = 1.0.
Order of approximations
−f″(0)
−θ′(0)
−ϕ′(0)
1
0.86392
0.70881
0.76889
5
0.89486
0.70474
0.87450
10
0.92546
0.70257
0.90333
15
0.92925
0.70104
0.91300
20
0.93900
0.70152
0.91448
25
0.93903
0.70156
0.91563
30
0.93903
0.70156
0.91563
4 Results and Discussion
The results obtained for velocity, temperature and concentration distributions are presented graphically for prominent arising physical parameters. A comparison of flow behavior past a stretched cylinder versus a flat plat is also portrayed. Moreover, graphical illustrations depicting impact of prominent parameters on skin friction, local Nusselt and Sherwood numbers are also added to the present exploration. From Fig 3, it is perceived that the velocity profile is diminishing function of Hartmann number Ha. This upsurge in Hartmann number results in increase in Lorentz force. Lorentz force is a resistive force therefore attenuation in velocity profile is perceived. Furthermore, it is observed that impact of magnetic parameter is weaker in plate as compared to cylinder. Fig 4 illustrates that velocity distribution results in the mounting function of stagnation point parameter P0 in both cases when P0 < 1 and P0 > 1. This is because of the fact that cylinder’s stretching velocity is much smaller in comparison to free stream velocity. It is also noted that there is no boundary layer for P0 = 1 due to the fact that both fluid and cylinder are moving with similar velocity. Fig 5 portrays the concentration field for varied values of chemical reaction parameter Q0. Reduction in solute nanoparticle concentration and its allied boundary layer thickness is seen because of heavy disturbance in fluid’s molecules. The influence of radiation parameter Rd on temperature profile is examined in Fig 6. It shows that an increase in radiative parameter enhances the temperature distribution. Actually, more heat is transferred to the fluid due to higher values of radiation parameter. Moreover, it is observed that radiation effects are stronger in case of the cylinder as compared to the plate. Figs 7 and 8 depict the impact of Lewis number Le on temperature and nanoparticle concentration fields respectively and show that both profiles are decreasing functions of Le. Eventually, in the examination, a thin concentration boundary layer with frail molecular diffusivity is observed. Fig 9 shows that with gradual growth in thermal stratification e, temperature distribution also show a tendency to decline. This is because of temperature differences between sheet and ambient fluid which lowers the temperature field. The same fact holds in case of solutal stratification j and can be observed in Fig 10 where concentration profile is also the decreasing function of solutal stratification. The effects of thermophoresis parameter Nt on temperature and nanoparticle concentration are illustrated in Figs 11 and 12 respectively and it is perceived that both distributions are mounting functions of Nt. Due to increasing values of Nt, more nanoparticles are pulled towards the cold surface from the hot one which ultimately results in increasing the temperature and concentration distributions. Higher values of Brownian motion parameter Nb results in an upsurge in the temperature field but a decrease in the nanoparticle concentration profile. Both the effects are depicted in Figs 13 and 14 respectively. In fact, gradual growth in Nb increases the random motion and collision among nanoparticles of the fluid which produces more heat and eventually results in an increase in temperature distribution and decrease in concentration field. Figs 15 and 16 are drawn to bear witness to the variation in temperature and solutal concentration distributions for the mounting values of Prandtl number Pr. From these illustrations it can be seen that increasing values of Pr results in reducing the temperature and concentration profiles. As Prandtl number is the quotient of momentum diffusivity to thermal diffusivity. Therefore, larger values of Pr result because of smaller thermal diffusivity which ultimately lowers both temperature and concentration fields. Fig 17 represent the influence of Hartmann number Ha and fluid parameter M on skin friction coefficient. It is clear from the figure that skin friction coefficient is increasing function of both Ha and M. The effects of thermophoresis Nt and Brownian motion Nb parameters on local Nusselt number are displayed in Fig 18. It is detected that increasing the values of Nt and Nb, results in lowering local Nusselt number. Fig 19 is plotted to show the impact of Prandtl Pr and Lewis Le numbers on Sherwood number. Here, it is noted that Sherwood number is mounting function of both Pr and Le. However, from Fig 20, it is clear that Sherwood number is increasing and decreasing function of Nb and Nt respectively.
10.1371/journal.pone.0170790.g003
Influence of Ha on f′(η).
10.1371/journal.pone.0170790.g004
Influence of P0 on f′(η).
10.1371/journal.pone.0170790.g005
Influence of Q0 on ϕ(η).
10.1371/journal.pone.0170790.g006
Influence of Rd on θ(η).
10.1371/journal.pone.0170790.g007
Influence of Le on θ(η).
10.1371/journal.pone.0170790.g008
Influence of Le on ϕ(η).
10.1371/journal.pone.0170790.g009
Influence of e on θ(η).
10.1371/journal.pone.0170790.g010
Influence of j on ϕ(η).
10.1371/journal.pone.0170790.g011
Influence of Nt on θ(η).
10.1371/journal.pone.0170790.g012
Influence of Nt on ϕ(η).
10.1371/journal.pone.0170790.g013
Influence of Nb on θ(η).
10.1371/journal.pone.0170790.g014
Influence of Nb on ϕ(η).
10.1371/journal.pone.0170790.g015
Influence of Pr on θ(η).
10.1371/journal.pone.0170790.g016
Influence of Pr on ϕ(η).
10.1371/journal.pone.0170790.g017
Influence of Ha and M on CfRe1/2.
10.1371/journal.pone.0170790.g018
Influence of Nt and Nb on −θ′(0).
10.1371/journal.pone.0170790.g019
Influence of Pr and Le on −ϕ′(0).
10.1371/journal.pone.0170790.g020
Influence of Nt and Nb on −ϕ′(0).
In Table 2, a comparison to the previous exploration in the limiting case for the Sherwood number is presented. All obtained results are found in excellent agreement.
10.1371/journal.pone.0170790.t002
Comparison of values of Sherwood number in limiting case for varied values of M, λ, Ha, γ, Pr, Nt, Nb, Rd and Le when P0 = e = j = Q0 = 0.
M
λ
Ha
γ
Pr
Nt
Nb
Rd
Le
Hayat et al. [34]
Present
0.2
0.1
0.2
0.1
1.2
0.1
0.1
0.1
1.3
0.6658
0.6658
0.4
0.6849
0.6849
0.6
0.7008
0.7008
0.2
0.1
0.6658
0.6658
0.5
0.6641
0.6641
0.7
0.6633
0.6633
0.1
0.2
0.6658
0.6658
0.5
0.6377
0.6377
0.7
0.6080
0.6080
0.2
0.1
0.6658
0.6658
0.3
0.7497
0.7497
0.5
0.8318
0.8318
0.1
0.7
0.8657
0.8657
1.2
0.6658
0.6658
1.7
0.4896
0.4896
1.2
0.10
0.6658
0.6658
0.20
0.1311
0.1311
0.22
0.0279
0.0279
0.1
0.1
0.6658
0.6658
0.3
0.7869
0.7869
0.5
1.140
1.140
0.1
0.6658
0.6658
0.4
0.7869
0.7869
0.7
0.8671
0.8671
0.9
0.3601
0.3601
1.3
0.6658
0.6658
1.7
0.9193
0.9193
5 Final remarks
The present study explores the effects of double stratification and magnetohydrodynamic flow of Eyring Powell nanofluid past a stretched cylinder near stagnation point. The analysis is done in the presence of chemical reaction and thermal radiation. Homotopy analysis method is used in order to obtain the series solutions of the said problem. The salient features of the present study are as following.
Increasing the values of chemical reaction parameter results in reducing the solute nanoparticle concentration.
Velocity profile decreases when radiation parameter increases.
Sherwood number is increasing and decreasing function of Nb and Nt respectively.
Gradual growth in thermal and solutal stratification results in decline in the temperature and concentration distributions respectively.
Higher values of Brownian motion parameter Nb increase the temperature field but decrease the nanoparticle concentration profile.
This work was supported by the World Class 300 Project (No. S2367878) of the SMBA (Korea).
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