The two-dimensional magnetohydrodynamic (MHD) stagnation-point flow of electrically conducting non-Newtonian Casson fluid and heat transfer towards a stretching sheet have been considered. The effect of thermal radiation is also investigated. Implementing similarity transformations, the governing momentum, and energy equations are transformed to self-similar nonlinear ODEs and numerical computations are performed to solve those. The investigation reveals many important aspects of flow and heat transfer. If velocity ratio parameter (B) and magnetic parameter (M) increase, then the velocity boundary layer thickness becomes thinner. On the other hand, for Casson fluid it is found that the velocity boundary layer thickness is larger compared to that of Newtonian fluid. The magnitude of wall skin-friction coefficient reduces with Casson parameter (β). The velocity ratio parameter, Casson parameter, and magnetic parameter also have major effects on temperature distribution. The heat transfer rate is enhanced with increasing values of velocity ratio parameter. The rate of heat transfer is enhanced with increasing magnetic parameter M for B > 1 and it decreases with M for B < 1. Moreover, the presence of thermal radiation reduces temperature and thermal boundary layer thickness.
1. Introduction
In fluid dynamics the effects of external magnetic field on magnetohydrodynamic (MHD) flow over a stretching sheet are very important due to its applications in many engineering problems, such as glass manufacturing, geophysics, paper production, and purification of crude oil. The flow due to stretching of a flat surface was first investigated by Crane [1]. Pavlov [2] studied the effect of external magnetic field on the MHD flow over a stretching sheet. Andersson [3] discussed the MHD flow of viscous fluid on a stretching sheet and Mukhopadhyay et al. [4] presented the MHD flow and heat transfer over a stretching sheet with variable fluid viscosity. On the other hand, Fang and Zhang [5] reported the exact solution of MHD flow due to a shrinking sheet with wall mass suction. Bhattacharyya and Layek [6] showed the behavior of solute distribution in MHD boundary layer flow past a stretching sheet. Furthermore, many vital properties of MHD flow over stretching sheet were explored in various articles [7–12] in the literature. Several important investigations on the flow due to stretching/shrinking sheet are available in the literature [13–16].
Chiam [17] investigated the stagnation-point flow towards a stretching sheet with the stretching velocity of the plate being equal to the straining velocity of the stagnation-point flow and found no boundary layer structure near the sheet. Mahapatra and Gupta [18] reconsidered the stagnation-point flow problem towards a stretching sheet taking different stretching and straining velocities and they observed two different kinds of boundary layer near the sheet depending on the ratio of the stretching and straining constants. The detailed discussion on the stagnation-point flow over stretching/shrinking sheet can be found in the works of Mahapatra and Gupta [19], Nazar et al. [20], Layek et al. [21], Nadeem et al. [22], Bhattacharyya [23–25], Bhattacharyya et al. [26–28], Bhattacharyya and Vajravelu [29], and Van Gorder et al. [30].
Many fluids used in industries show non-Newtonian behaviour, so the modern-day researchers are more interested in those industrial non-Newtonian fluids and their dynamics. A single constitutive equation is not enough to cover all properties of such non-Newtonian fluids and hence many non-Newtonian fluid models [31–34] have been proposed to clarify all physical behaviours. Casson fluid is one of the types of such non-Newtonian fluids, which behaves like an elastic solid, and for this fluid, a yield shear stress exists in the constitutive equation. Fredrickson [35] investigated the steady flow of a Casson fluid in a tube. The unsteady boundary layer flow and heat transfer of a Casson fluid over a moving flat plate with a parallel free stream were studied by Mustafa et al. [36] and they solved the problem analytically using homotopy analysis method (HAM). Bhattacharyya et al. [37, 38] reported the exact solution for boundary layer flow of Casson fluid over a permeable stretching/shrinking sheet with and without external magnetic field. The important characteristics of the flows of various non-Newtonian fluids over a stretching/shrinking sheet can be found in the articles [39–46].
Motivated by the previously mentioned investigations on flow of non-Newtonian fluids due to a stretching sheet and its vast applications in many industries, in the present paper, the steady two-dimensional MHD stagnation-point flow of electrically conducting non-Newtonian Casson fluid and heat transfer past a stretching sheet in presence of thermal radiation effect are investigated. Using similarity transformations, the governing equations are transformed. The converted self-similar ordinary differential equations are solved by shooting method. The numerical results are plotted in some figures to see the effects of physical parameters on the flow and heat transfer.
2. Mathematical Analysis of the Flow
Consider the steady two-dimensional incompressible flow of electrically conducting Casson fluid bounded by a stretching sheet at y=0, with the flow being confined in y>0. It is also assumed that the rheological equation of state for an isotropic and incompressible flow of a Casson fluid can be written as [37, 47]
(1)τij={(μB+py2π)2eij,π>πc,(μB+py2πc)2eij,π<πc,
where μB is plastic dynamic viscosity of the non-Newtonian fluid, py is the yield stress of fluid, π is the product of the component of deformation rate with itself, namely, π=eijeij, eij is the (i,j)th component of the deformation rate, and πc is critical value of π based on non-Newtonian model.
Under the previous conditions, the MHD boundary layer equations for steady stagnation-point flow can be written as
(2)∂u∂x+∂v∂y=0,(3)u∂u∂x+v∂u∂y=UsdUsdx+υ(1+1β)∂2u∂y2-σH02ρ(u-Us),
where u and v are the velocity components in x and y directions, respectively, Us=ax is the straining velocity of the stagnation-point flow with a (>0) being the straining constant, υ is the kinematic fluid viscosity, ρ is the fluid density, β=μB2πc/py is the non-Newtonian or Casson parameter, σ is the electrical conductivity of the fluid, and H0 is the strength of magnetic field applied in the y direction, with the induced magnetic field being neglected.
The boundary conditions for the velocity components are
(4)u=Uw,v=0aty=0,u⟶Usasy⟶∞,
where Uw=cx is stretching velocity of the sheet with c (>0) being the stretching constant.
The stream function Ψ is introduced as
(5)u=∂Ψ∂y,v=-∂Ψ∂x.
For relations of (5), (2) is satisfied automatically and (3) takes the following form:
(6)∂Ψ∂y∂2Ψ∂x∂y-∂Ψ∂x∂2Ψ∂y2=UsdUsdx+υ(1+1β)∂3Ψ∂y3-σH02ρ(∂Ψ∂y-Us).
Also, boundary conditions in (4) reduce to
(7)∂Ψ∂y=Uw,∂Ψ∂x=0,aty=0,∂Ψ∂y⟶Usasy⟶∞.
Now, the dimensionless variable for the stream function is implemented as
(8)Ψ=cυxf(η),
where the similarity variable η is given by η=yc/υ.
Using relation (8) and similarity variable, (6) finally takes the following self-similar form:
(9)(1+1β)f′′′+ff′′-f′2-M(f′-B)+B2=0,
where primes denote differentiation with respect to η, M=σH02/ρc is the magnetic parameter, and B=a/c is the velocity ratio parameter.
The boundary conditions reduce to
(10)f(η)=0,f′(η)=1atη=0,f′(η)⟶Basη⟶∞.
3. Analysis of Heat Transfer
For the temperature distribution in the flow field with thermal radiation, the governing energy equation can be written as
(11)u∂T∂x+v∂T∂y=κρcp∂2T∂y2-1ρcp∂qr∂y,
where T is the temperature, κ is the thermal conductivity, cp is the specific heat, and qr is the radiative heat flux.
The appropriate boundary conditions are
(12)T=Twaty=0,T⟶T∞asy⟶∞,
where Tw is the constant temperature at the sheet and T∞ is the free stream temperature assumed to be constant.
Using the Rosseland approximation for radiation [48], qr=-(4σ*/3k1)∂T4/∂y is obtained, where σ* is the Stefan-Boltzmann constant and k1 is the absorption coefficient. We presume that the temperature variation within the flow is such that T4 may be expanded in a Taylor’s series. Expanding T4 about T∞ and neglecting higher-order terms we get T4=4T∞3T-3T∞4.
Now (11) reduces to
(13)u∂T∂x+v∂T∂y=κρcp∂2T∂y2+16σT∞33k1ρcp∂2T∂y2.
Next, the dimensionless temperature θ is introduced as
(14)θ(η)=T-T∞Tw-T∞.
Using (8), (14), and the similarity variable, (13) reduces to
(15)(3R+4)θ′′+3RPrfθ′=0,
where primes denote differentiation with respect to η, Pr=cpμ/κ is the Prandtl number, and R=κ*k1/4σT∞3 is the thermal radiation parameter.
The boundary conditions for θ are obtained from (12) as
(16)θ(η)=1atη=0,θ(η)⟶0asη⟶∞.
4. Skin Friction Coefficient and Nusselt Number
The physical quantities of interest are the wall skin friction coefficient Cf and the local Nusselt number Nux, which are defined as
(17)Cf=τwρUw2(x),Nux=xqwα(Tw-T∞),
where τw is the shear stress or skin friction along the stretching sheet and qw is the heat flux from the sheet and those are defined as
(18)τw=(μB+py2π)(∂u∂y)y=0,qw=α(∂T∂y)y=0.
Thus, we get the wall skin friction coefficient Cf and the local Nusselt number Nux as follows:
(19)CfRex=(1+1β)f′′(0),NuxRex=-θ′(0),
where Rex=Uwx/υ is the local Reynolds number.
5. Numerical Method for Solution
Equations (9) and (15) along with boundary conditions (10) and (16) are solved using shooting method [49–51] by converting them to an initial value problem. In this method, it is necessary to choose a suitable finite value of η→∞, say η∞. The following system is set
(20)f′=p,p′=q,q′={p2+M(p-B)-fq-B2}(1+1/β),θ′=z,z′=3RPrfz(3R+4)
with the boundary conditions
(21)f(0)=0,p(0)=1,θ(0)=1.
In order to integrate (20) with (21) as an initial value problem, the values of q(0), that is, f′′(0) and z(0), that is, θ′(0), are required, but no such values are given in the boundary conditions. The suitable guess values for f′′(0) and θ′(0) are chosen and then integration is carried out. Then, the calculated values for f′and θ at η∞=15 (say) are compared with the given boundary conditions f′(15)=B and θ(15)=0 and the estimated values, f′′(0) and θ′(0), are adjusted to give a better approximation for the solution. We take the series of values for f′′(0) and θ′(0) and apply the fourth-order classical Runge-Kutta method with step-size Δη=0.01. The previous procedure is repeated until we get the asymptotically converged results within a tolerance level of 10−5.
6. Results and Discussion
The abovementioned numerical scheme is carried out for various values of physical parameters, namely, the velocity ratio parameter (B), the magnetic parameter (M), the Casson parameter (β), the Prandtl number (Pr), and the thermal radiation parameter (R) to obtain the effects of those parameters on dimensionless velocity and temperature distributions. The obtained computational results are presented graphically in Figures 1–12 and the variations in velocity and temperature are discussed.
Velocity profiles f(η) for several values of B.
Temperature profiles θ(η) for several values of B.
Velocity profiles f(η) for several values of β.
Temperature profiles θ(η) for several values of β.
Velocity profiles f(η) for several values of M.
Temperature profiles θ(η) for several values of M.
Temperature profiles θ(η) for several values of Pr.
Temperature profiles θ(η) for several values of R.
The values of (1+1/β)f′′(0) for several values of B and M.
The values of -θ′(0) for several values of B and M.
The values of (1+1/β)f′′(0) for several values of β and M.
The values of -θ′(0) for several values of β and M.
Firstly, a comparison of the obtained results with previously published data is performed. The values of wall skin-friction coefficient f′′(0) for Newtonian fluid case (β=∞) in the absence of external magnetic field for different values of velocity ratio parameter (B) are compared with those obtained by Mahapatra and Gupta [19], Nazar et al. [20] in Table 1 in order to verify the validity of the numerical scheme used and those are found in excellent agreement.
Values of f′′(0) for several values of B with M=0 and β=∞ (Newtonian fluid case without magnetic field).
B
Mahapatra and Gupta [19]
Nazar et al. [20]
Present study
0.1
−0.9694
−0.9694
−0.969386
0.2
−0.9181
−0.9181
−0.918107
0.5
−0.6673
−0.6673
−0.667263
2.0
2.0175
2.0176
2.017503
3.0
4.7293
4.7296
4.729284
The velocity boundary layer thickness (δ) and thermal boundary layer thickness (δT) are, respectively, described by the equations δ=ηδυ/c and δT=ηδTυ/c. The dimensionless boundary layer thicknesses ηδ and ηδT are defined as the values of η (nondimensional distance from the surface) at which the difference of dimensionless velocity f′(η) and the parameter B has been reduced to 0.001 and the dimensionless temperature θ(η) has been decayed to 0.001, respectively. The velocity and thermal boundary layer thicknesses for various parametric values are given in Table 2. The velocity boundary layer thickness decreases with increasing values B (both for B>1 and B<1) and also the thermal boundary layer thickness decreases with increasing B. So, when the straining velocity rate increases compared to that of stretching velocity rate, then both the boundary layer thicknesses reduce. Actually, downward vorticity due to straining velocity causes the reduction of boundary layer thickness. Similar to velocity ratio parameter, the increase of Casson parameter β also makes the velocity boundary layer thickness thinner. So, the velocity boundary layer thickness for Casson fluid is larger than that of Newtonian fluid. Thus, the plasticity of the fluid causes the increment of the velocity boundary layer thickness. On the other hand, for B=0.1 (<1), the thermal boundary layer thickness increases with increasing values of Casson parameter, but for B=2 (>1) the thermal boundary layer thickness decreases with Casson parameter. Furthermore, due to magnetic field, the velocity boundary layer thickness reduces in all cases. But the thermal boundary layer thickness reduces (increases) for B=2 (B=0.1) with stronger magnetic field. Finally, for the Prandtl number and for radiation parameter, the thermal boundary layer thickness decreases, which is the same as that of Newtonian fluid case.
Values of ηδ and ηδT for several values of B, β, M, Pr, and R.
β=2, M=0.5, Pr=1, R=1
B→
0.1
0.5
1
1.5
2.0
ηδ
5.76
4.81
—
2.59
2.48
ηδT
10.78
6.59
5.04
4.25
3.75
M=0.5, Pr=1, R=1
β→
0.5
1
2
5
∞
ηδ
B=0.1
8.14
6.65
5.76
5.15
4.70
B=2
3.50
2.86
2.48
2.22
2.03
ηδT
B=0.1
9.45
10.24
10.78
11.17
11.48
B=2
3.82
3.78
3.75
3.73
3.72
β=2, Pr=1, R=1
M→
0
0.5
1
2
ηδ
B=0.1
6.49
5.76
5.20
4.43
B=2
2.53
2.48
2.43
2.33
ηδT
B=0.1
10.17
10.78
11.21
11.75
B=2
3.76
3.75
3.74
3.73
β=2, M=0.5, R=1
Pr→
0.5
1
2
ηδT
B=0.1
14.46
10.78
6.69
B=2
5.22
3.75
2.70
β=2, M=0.5, Pr=1
R→
1
2
5
ηδT
B=0.1
10.78
8.58
7.09
B=2
3.75
3.20
2.81
The velocity and temperature profiles for various values of velocity ratio parameter B are plotted in Figures 1 and 2, respectively. Depending on the velocity ratio parameter, two different kinds of boundary layers are obtained as described by Mahapatra and Gupta [18] for Newtonian fluid. In the first kind, the velocity of fluid inside the boundary layer decreases from the surface towards the edge of the layer (for B<1) and in the second kind the fluid velocity increases from the surface towards the edge (for B>1). Those characters can be seen from velocity profiles in Figure 1. Also, it is important to note that if B=1 (a=c), that is, the stretching velocity and the straining velocity are equal, then there is no boundary layer of Casson fluid flow near the sheet, which is similar to that of Chiam’s [17] observation for Newtonian fluid. From Figure 2, it is seen that in all cases thermal boundary layer is formed and the temperature at a point decreases with B.
The effects of Casson parameter β on the velocity and temperature fields are depicted in Figures 3 and 4. It is worthwhile to note that the velocity increases with the increase in values of β for B=2 and it decreases with β for B=0.1. Consequently, the velocity boundary layer thickness reduces for both values of B. Due to the increase of Casson parameter β, the yield stress py falls and consequently velocity boundary layer thickness decreases. The influences of Casson parameter on the temperature profiles are different in two cases, B=2 and B=0.1. Temperature at a point decreases with increasing β for B=2 and increases with increasing β for B=0.1.
In Figures 5 and 6, the velocity and temperature profiles are presented for several values of magnetic parameter M. Similar to that of Casson parameter, due to the increase of magnetic parameter the dimensionless velocity at fixed η increases for B=2 and for B=0.1 the velocity decreases. Consequently, for both types of boundary layers, the thickness decreases. The Lorentz force induced by the dual actions of electric and magnetic fields reduces the velocity boundary layer thickness by opposing the transport phenomenon. Also, for B=2, the temperature decreases with M and increases with M for B=0.1.
The dimensionless temperature profiles θ(η) for several values of Prandtl Number Pr and thermal radiation parameter R are exhibited in Figures 7 and 8, respectively, for two values of B. In both cases (B=0.1 and 2), the temperature decreases with increasing values of Prandtl number and radiation parameter and the thermal boundary layer thickness becomes smaller in all cases. Actually, the rate of heat transfer is enhanced with Prandtl Number and radiation parameter and this causes the reduction of thermal boundary layer thickness.
The physical quantities, the wall skin friction coefficient Cf, and the local Nusselt number Nux, which have immense engineering applications, are proportional to the values of (1+1/β)f′′(0) and -θ′(0), respectively. The values of (1+1/β)f′′(0) and -θ′(0) against the magnetic parameter M are plotted in Figures 9 and 10 for different values of B. From the figures, it is observed that the magnitude of wall skin friction coefficient decreases with increasing values of velocity ratio parameter B when B<0.1, whereas for B>0.1 the magnitude of skin-friction increases with B. The local Nusselt number (Figure 10) increases with B; that is, the heat transfer rate is enhanced with B. Due to higher values of Casson parameter β, the magnitude of (1+1/β)f′′(0) decreases (Figure 11) for both values of B (for B>1 as well as for B<1). On the other hand, the value of -θ′(0), that is, the heat transfer (Figure 12), increases with β for B=2 (>1) and decreases with β when B=0.1 (<1). Finally, from those figures (Figures 9–12), it can be noticed that the wall skin friction coefficient always becomes larger when the external magnetic field is stronger and the rate of heat transfer is enhanced (reduced) with increasing magnetic parameter M for B>1 (B<1).
7. Conclusions
The MHD stagnation-point flow of Casson fluid and heat transfer over a stretching sheet are investigated taking into consideration the thermal radiation effect. Using similarity transformations, the governing equations are transformed to self-similar ordinary differential equations which are then solved using shooting method. From the study, the following remarks can be summarized.
The velocity boundary layer thickness reduces with velocity ratio parameter and magnetic parameter.
The velocity boundary layer thickness for Casson fluid is larger than that of Newtonian fluid.
For Casson fluid, that is, for decrease of Casson parameter, the thermal boundary layer thickness decreases for B=0.1 (<1) and, in contrast, for B=2 (>1) the thickness increases.
Due to thermal radiation, the temperature inside the boundary layer decreases.
The magnitude of wall skin-friction coefficient decreases with Casson parameter β.
Nomenclaturea:
Straining constant
B:
Velocity ratio parameter
c:
Stretching constant
Cf:
Wall skin friction coefficient
cp:
Specific heat
f:
Dimensionless stream function
f′:
Dimensionless velocity
H0:
Strength of magnetic field applied in the y direction
k1:
Absorption coefficient
M:
Magnetic parameter
Nux:
Local Nusselt number
Pr:
Prandtl number
p:
A variable
py:
Yield stress of fluid
q:
A variable
qr:
Radiative heat flux
qw:
Heat flux from the sheet
R:
Thermal radiation parameter
Rex:
Local Reynolds number
T:
Temperature
Tw:
Constant temperature at the sheet
T∞:
Free stream temperature
Us:
Straining velocity of the stagnation-point flow
Uw:
Stretching velocity of the sheet
u:
Velocity component in x direction
v:
Velocity component in y direction
x:
Distance along the sheet
y:
Distance perpendicular to the sheet
z:
A variable.
Greek Symbolsβ:
Non-Newtonian/Casson parameter
δ:
Velocity boundary layer thickness
δT:
Thermal boundary layer thickness
η:
Similarity variable
η∞:
Finite value of η
ηδ:
Dimensionless velocity boundary layer thickness
ηδT:
Dimensionless thermal boundary layer thickness
κ:
Thermal conductivity
μB:
Plastic dynamic viscosity of the non-Newtonian fluid
π:
Product of the component of deformation rate with itself
πc:
Critical value of π
υ:
Kinematic fluid viscosity
ρ:
Fluid density
Ψ:
Stream function
σ:
Electrical conductivity of the fluid
σ*:
Stefan-Boltzmann constant
τw:
Shear stress
θ:
Dimensionless temperature.
Conflict of Interests
The author declares that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
The author gratefully acknowledges the financial support of the National Board for Higher Mathematics (NBHM), Department of Atomic Energy, Government of India, for pursuing this work. The author also thanks the referees for their valuable comments and suggestions which helped a lot in the improvement of the quality of the paper.
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