Unsteady MHD Flow of Nanofluid with Variable Properties over a Stretching Sheet in the Presence of Thermal Radiation and Chemical Reaction

Mjankwi, Musa Antidius; Masanja, Verdiana Grace; Mureithi, Eunice W.; James, Makungu Ng’oga

doi:https://doi.org/10.1155/2019/7392459

International Journal of Mathematics and Mathematical Sciences

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Abstract Introduction Results and Discussion Conclusion Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2019 | Article ID 7392459 | https://doi.org/10.1155/2019/7392459

Unsteady MHD Flow of Nanofluid with Variable Properties over a Stretching Sheet in the Presence of Thermal Radiation and Chemical Reaction

Musa Antidius Mjankwi,¹Verdiana Grace Masanja,¹Eunice W. Mureithi,²and Makungu Ng’oga James²

Academic Editor: Hernando Quevedo

Received28 Dec 2018

Revised24 Mar 2019

Accepted07 Apr 2019

Published02 May 2019

Abstract

The unsteady magnetohydrodynamics (MHD) flow of nanofluid with variable fluid properties over an inclined stretching sheet in the presence of thermal radiation and chemical reaction is studied taking into account the effect of variable fluid properties in thermal conductivity and diffusion coefficient. The governing partial differential equations are transformed into ordinary differential equations by using similarity transformation. The numerical solutions of the problem are obtained by using the fourth order Runge-Kutta method in line with the shooting technique. It is found that the increase in both thermal conductivity and radiative heat flux decreases the heat transfer rate but increases the skin friction and mass transfer rates. It is further observed that the increase in porosity parameter and magnetic field reduces the skin friction, heat, and mass transfer rates.

1. Introduction

The study concerned with the fluid flow over a stretching sheet has created many applications in industries among which are polymer industries, aerodynamic extrusion of plastic sheets, glass-fiber production, condensation process of a metallic plate in a cooling bath, and glass. Such studies were first initiated by Sakiadis [1] who simplified the convection term in the momentum equation by assuming that all convections take place at a constant velocity of a moving object. Following this pioneering work, the study of fluid flow over a continuous surface moving with either constant or variable velocity received wide attention among researchers such as Crane [2], Chen and Char [3].

Erickson et al. [4] extended the Sakiadis [1] study by introducing the effects of momentum, heat transfer, and mass transfer on the surface that is moving at constant speed. This study was further extended by Gupta [5] who added new parameters of suction, injection and considered the sheet to be stretched with a linear speed. In all of these studies, the commonly coolant fluids used were oils, water, and ethylene glycol; however, these fluids had relatively low thermal conductivity and stability.

In recent year, it has been proposed to mix up nanoparticles (10-50nm) and base fluids (oils, water, and ethylene glycol) to form the fluid commonly known as nanofluids. The presence of nanoparticles in these fluids has significant effects on the physical properties of the fluid and causes a major increase in the heat transfer as presented by Hussain et al. [6] and Hussain et al. [7]. The presence of magnetic nanoparticles in these fluids makes nanofluid to be among the electrically conducting fluids. The study of magnetic properties and the behavior of electrically conducting fluids are well known as hydromagnetics or magnetofluid dynamics or magnetohydrodynamics (MHD).

MHD laminar boundary layer flow behavior over a stretching surface is an important type of flow with considerable practical applications in electrochemistry, chemical engineering, geophysics, astrophysics, and polymer processing. This is due to the fact that MHD absorbs energy and produces a controllable behavior; as a result, it can be controlled and directed by using external magnetic fields and hence slowing the rate of solidification of the cooled material and improving its mechanical properties as presented by Makinde [8], Hussain et al. [9], and Hussain et al. [6].

The characteristic of nanofluid under the effect of magnetic fields becomes the most attractive method in this process as it is simple to use and because of its uniqueness and nature. Hussain [10] in his study on the effect of MHD flow of nanofluids with heat and mass transfer through a porous media with thermal radiation, viscous dissipation, and chemical reaction observed that the dimensionless velocity profiles of nanofluids decrease as the magnetic field and permeability of the porous medium parameter increase.

The same results were observed by Ahmmed et al. [11] while performing the research in unsteady MHD free convection flow of nanofluid through an exponentially accelerated inclined plate embedded in a porous medium with variable thermal conductivity in the presence of thermal radiation. Experimentally, this finding means as the strength of external magnet increases, the flow speed of the magnetic nanofluid decreases; hence, nanofluids cool the intended object such as sheets or plates.

Haile and Shankar [12] in their study on the effects of thermal radiation, viscous dissipation, and chemical reaction on heat and mass transfer of MHD flow of nanofluids through a porous medium observed that as the thermal radiation or viscous dissipation increases, it causes increase in temperature of the coolant fluid. Also, as the chemical reaction parameter increases, the concentration of fluid decreases in the boundary layer flow. Uddin et al. [13] while analyzing the free convection flow of magnetic nanofluid with chemical reaction observed that as the flow velocity is reduced by the magnetic field, the temperature of the fluid increases.

Mehmood et al. [14] while performing the research on the effects of nonlinear thermal radiation and inclined magnetic field based on MHD in aluminum water nanofluid observed that the increase in magnetic field inclined angle results in the decrease in average Nusselt number. Hussain et al. [15] studied the effects of inclined angle on mixed convection nanofluid flow in a double lid-driven with discrete heat source and concluded that the increase in inclination angle causes the increase in average Nusselt number.

Sheikholeslami et al. [16] in their study on the effects of magnetic field on the forced convection flow of nanofluids over a stretching surface concluded that momentum boundary layer thickness decreases as the magnetic parameter increases. However, in the research presented by Haile and Shankar [12], Uddin et al.[13] and Sheikholeslami et al. [16], the physical parameters of the coolant fluid such as fluids viscosity, thermal conductivity, diffusion coefficient, and fluid density were treated constantly. In fact, the temperature of the hot stretched sheet causes the temperature of the coolant fluid to change. This effect makes the physical parameters of the coolant fluid to be temperature dependent.

For this reason some researchers, for instance, James et al. [17, 18], in their studies considered the effects of temperature-dependent viscosity in the steady flow and observed that an increase in viscosity results in the increase of both heat and mass transfer rate. This means the fluid with higher viscosity cools well the hot stretched sheet. Reddy and Chamkha [19] observed that an increase in thermal conductivity increases the temperature of the coolant fluid. Also an increase in variable diffusion coefficient resulted in the increase of concentration of the coolant fluid [20]. However, the flow under consideration in all the above studies was steady flow of the fluid.

Based on the few researches that have been presented by James et al. [17, 18], Reddy and Chamkha [19], the variations of fluid properties of the coolant nanofluid should be considered when analyzing the heat and mass transfer flow over a hot sheet or plate because they play an important role during the cooling processes. Proper consideration of these effects will lead to the higher increase of the mechanical properties of the cooled materials such as the strength of the sheets or plates. However, all of the studies cited above were governed by the steady flow of which by nature it is not true.

In real situations, the flow of fluids induced by stretched sheets involving heat transfer is unsteady in nature due to the sudden motion of the stretched sheet, change of temperature of the sheet and that of fluids and also due to the sudden change of concentration of nanofluids. The study becomes significant when the flow is unsteady and with variable physical parameters as presented by Hunegnaw and Kishan [21], Shukla and Rana [22], Sulochana and Kumar [23], and Venkataramanaiah [24].

Experimental studies have established that the physical properties of magnetic nanofluids change with varying average particles size, changing in nanoparticle shape and the nature of base fluid used as presented by Rao and Ranganayakulu [25]. These findings influenced researchers like Mutuku [26] who proposed the modifications of some cooling systems (e.g., car radiators) or cooled materials (e.g., stretched sheet) by including the effect of external magnetic field against nanofluid (coolant fluids) so as to control the fluid flow for effective cooling.

If the flow speed of magnetic nanofluid will be controlled or directed by external magnetic fields, the magnetic nanofluid will stay at the same hot point for some time. This will cause the fluid properties such as density, thermal conductivity, diffusion coefficient, and fluid viscosity to vary with respect to temperature. Consequently, for higher variations it might cause the effects in cooling processes and, thus, further studies on the effect of variation of fluid properties with respect to temperature are needed.

In most cases, the thermal conductivity is modeled as a linear function of temperature. On the other hand, the diffusion coefficient (D) depends on molecular size, temperature, pressure, and other properties of the diffusing substance. This means, with an exception of temperature, if all other parameters are kept constant, then the diffusion coefficient can be modeled as a function of temperature. Alsabery et al. [27] in their experimental research on conjugate natural convection of –water nanofluid in a square cavity with a concentric solid modeled the diffusion coefficient as linear function of temperature based on Einstein-Stoke’s equation for Brownian diffusion coefficient.

Gharagozloo and Goodson [28] in their experimental research based on temperature-dependent aggregation and diffusion in nanofluids modeled the diffusion coefficient to depend on temperature. In this study they observed that as the diffusion is slowed, it causes the reduction in concentration distribution. In view of several analogies between heat and mass transfer during cooling process, for instance in solidification of binary alloy and in extrusion of sheet based on coolant fluids such as nanofluids, one can model both thermal conductivity and diffusion coefficient as a liner function of temperature.

Inspired and motivated by the current research, the dependency of thermal conductivity and mass diffusivity on temperature occurs in many natural phenomena (e.g., photosynthesis) and technological processes like drying crystals, cooling of nuclear reactors, solar ponds, cooling process during solidification of binary alloy, and extrusion of sheet. Thus, the behavior of concentration and temperature of nanofluid under the effects of variation of thermal conductivity and diffusion coefficient as a function of temperature in the presence of thermal radiation and chemical reaction when nanofluids are used as coolant fluids needs investigations.

However, to the authors’ knowledge there are no studies that have been reported on unsteady MHD flow of nanofluids with variable fluid properties on both thermal conductivity and diffusion coefficient with regard to temperature change, over an inclined and permeable stretching sheet in the presence of thermal radiation and chemical reaction. The problem has an important application on cooling process for the purpose of improving mechanical properties of heated sheet that cannot be cooled by the use of traditional methods based on the base fluids.

In this research the model equations will be transformed into ordinary differential equations by using similarity transformation. Numerical shooting technique together with the fourth order Runge-Kutta scheme will be used to obtain numerical solutions of the model. The effects of nondimensional governing parameters such as variable thermal conductivity, variable diffusion coefficient, radiative heat flux, chemical reaction, porous medium, unsteadiness parameter, magnetic parameter, Prandtl number, Eckert number, Schmidt number, concentration Grashof number, thermal Grashof number, inclination angle and suction velocity parameter on dimensionless velocity, temperature, concentration profiles as well as skin friction, and Nusselt and Sherwood numbers will be discussed when magnetic nanofluids are applied as coolant fluid under the effects of external magnetic fields.

2. Formulation of the Problem

Consider unsteady two-dimensional incompressible laminar boundary layer MHD flow of a viscous nanofluid over a permeable inclined stretching sheet. The nanofluid is supplied heat by the stretching sheet and concentration of chemical species at uniform rates. It is assumed that the influence of density variation with temperature and concentration occurs only on the body force term and hence the changes in both concentration and temperature induce the buoyancy force. A uniform magnetic field is applied normal to the surface of the stretching sheet. Further, it is assumed that a homogeneous first order chemical reaction with thermal radiation is taking place in the flow. It is assumed that the velocity of the stretching sheet is in the direction of the force applied along the -axis and that of the mass transfer is normal to the stretched sheet. It is also assumed that the surface (wall) temperature and concentration of the sheet are and , respectively, while the uniform temperature and concentration far from the sheet are, respectively, and . In addition, it is assumed that the effect described by Fourier’s and Fick’s law is of higher order of magnitude than the effect due to Dufour and Soret and thus the Dufour and Soret effects are neglected. The fluid thermal conductivity and molecular diffusivity are assumed to vary as a linear function of temperature. The model flow diagram is illustrated in Figure 1.

Under these assumptions with the Boussinesq and boundary layer approximations, the governing model equations are given by equations (1) to (4):where is time, and are the velocity components in the and direction, respectively, is the mass density of the fluid, is the coefficient of viscosity, is the specific heat capacity at constant pressure, is the permeability, is the thermal conductivity, is the molecular diffusivity, and is the rate of chemical reaction. is the coefficient of volumetric thermal expansion, is the coefficient of volumetric expansion due to chemical species, is the temperature of the species, is the concentration of the species, and are ambient temperature and concentration, respectively, is the kinematic viscosity of the ambient fluid, is the electrical conductivity, is the strength of external magnetic field, is the acceleration due to gravity, is the radiation heat flux, and is the angle of inclination measured from the vertical axis to the stretching sheet.

The relevant boundary conditions are given in (5):where is the initial stretching rate, is a constant, and the subscripts and stand for the sheet and boundary layer edge (ambient conditions), respectively. The wall mass transfer velocity (or the fluid suction velocity) then becomes , and is a constant that describes the wall mass transfer parameter with the meaning that when , we have a suction, when , we have an impermeability, and when , we have an injection. The radiation heat flux is modeled by using the Rosseland’s (1972) approximation given in (6):where is the Stefan- Boltzmann constant and is the coefficient of absorption. It is also assumed that if the difference in temperature within the flow is , then can be expressed as a linear combination of the temperature by expanding the by Taylor’s series about to obtain (7):If we neglect the higher order beyond the first degree in in this series and opening brackets on the right-hand sides of (7) we obtain (8):Substituting the right-hand side of (8) into (6) for yield (9): The rate of change in radiative heat flux with respect to as presented by Mukhopadhyay [29] is given by (10):Substitution of (10) into the second term on the right-hand side of (3) changes (3) into (11):The temperature of the fluid at the surface of the sheet and the concentration of the fluid at the surface of the sheet are functions of time and distance and are assumed to be of the forms presented in (12). where in the absence of buoyancy force , which corresponds to the limit of forced convection.

2.1. Similarity Transformation

The partial differential equations (2), (4), and (11) are transformed into ordinary differential equations by introducing the dimensionless variables given by (13):and the relations given by (14): where is the free stream kinematic viscosity, is a stream function which defines the velocity components in the form , and it satisfies the continuity equation (1), represents injection and suction, is the dimensionless space variable, and and are dimensionless of temperature and concentration of the fluid, respectively.

Following Hunegnaw and Kishan [21] and Vajravelu [30] the thermal conductivity of nanofluid can vary linearly with temperature via a function shown in (15):and in terms of dimensionless temperature equation (15) reducing to equation (16):where is the variation thermal conductivity with respect to dimensionless temperature, is the thermal conductivity of the fluid far away from the heated sheet, and is a small parameter that depends on the nature of the fluid and it measures the rate of change of thermal conductivity with temperature.

In view of several analogies between heat and mass transfer during cooling process and following Dimian and Hadhoda [20], one can model the diffusion coefficient as a linear function of temperature shown in equation (17):Again as before, (17) may also be written in terms of dimensionless temperature as shown in where is the variation diffusion coefficient with respect to dimensionless temperature, is the diffusion coefficient of the fluid far away from the heated sheet and is a small parameter that depends on the nature of the fluid and it measures the rate of change of chemical diffusivity with temperature.

Using equations (12)-(14), (16) and (18), in equations (2), (4), (11) and (5) the following ordinary differential equations (19) to (21) are obtained:with the corresponding initial and boundary conditions in the dimensionless form given by equation (22):where , , , , , , , , , and are the unsteadiness parameter, porous medium parameter, magnetic parameter, thermal Grashof number, solutal or concentration Grashof number, Prandtl number, thermal radiation parameter, chemical reaction parameter, Eckert number, and the Schmidt number, respectively, and are defined in Note further the prime symbol denoting the differentiation with respect to dimensionless space variable . In this model the quantities of physical and practical engineering interest are the skin friction coefficient , the Nusselt number , and the Sherwood number which are defined in (24):In which, , , and are the skin friction or shear stress, heat flux, and mass flux from the sheet and are, respectively, given in (25):Substitutions of (13) and the relation (14) into (24) transform the skin friction, heat flux, and mass flux into (26) to (28), respectively:where , , and are the skin friction, Nusselt number, and Sherwood number, respectively; note further that is the local Reynolds number.

3. Numerical Solution of the Problem

In order to solve the system of ordinary differential equations (19)-(21) with their corresponding initial and boundary conditions (22) numerically, the domain has been substituted by the bounded domain where is a suitable finite real number that should be chosen in such a way that the solution satisfies the domain. Also (19)-(21) form a highly nonlinear coupled initial boundary value problem of third and second order ODEs. For this reason, (19)-(21) have been reduced to a system of seven initial problems of the first order of seven unknowns following the supposition in Thus we develop the most effective numerical shooting technique in line with the fourth order scheme. To solve this system, we require seven initial conditions whereas we have only four initial conditions for , , , and , while the other three , , and were not given; hence, we employ numerical shooting technique where these three initial conditions are guessed to produce the required three ending boundary conditions. The step size is used to obtain the numerical solution with eight decimals as a criterion of convergence.

4. Results and Discussion

Equations (19) to (21) with the corresponding initial and boundary conditions (22) have been solved numerically using the Runge-Kutta scheme together with shooting technique. The influence of the nondimensional governing parameters on velocity, temperature, concentration fields as well as friction factor, Nusselt number, and Sherwood number has been established by assigning some numerical values to the nondimensional parameters. The results obtained are discussed and presented through graphs and tables.

The nondimensional governing parameters in this research are suction/injection parameter , unsteadiness parameter , porous medium parameter , magnetic parameter , the thermal Grashof number , the solutal or concentration Grashof number , variable thermal conductivity parameter , variable diffusion coefficient parameter , the Prandtl number , the thermal radiation parameter , the chemical reaction parameter , the Eckert number , and Schmidt number .

With an exceptional of the varied parameters in Table 1 and on Figures 2–23 the values of these nondimensional parameters are considered to be constant throughout this study with their values , , , , , , , , , , , , and . To be realistic, the values of Prandtl number are chosen as and at 4°C which corresponds to water vapour, air and electrolytic solution, respectively, and the values of Schmidt number are chosen as and which corresponds to hydrogen, water vapour, ammonia, methanol and propyl benzene at 20°C, respectively, as presented by Shanker et al. [33].

In order to check the validity and accuracy of the present analysis, the results for heat transfer are compared with those reported by Ishak et al. [31] and Sandeep et al. [32] as shown in Table 1 and a good agreement has been observed.

Table 2 presents the effects of nondimensional governing parameters on the skin friction, Nusselt and Sherwood numbers. It is evident from the table that an increase in porosity parameter and magnetic field reduces the friction factor, heat and mass transfer rates. The increase in both thermal conductivity and radiative heat flux parameters decreases the heat transfer rate but increases the friction factor and mass transfer rates. Also the increase in thermal and concentration Grashof number increases the friction factor, heat and mass transfer rates.

Note further from Table 2 that the increase in diffusion coefficient results in the increase in skin friction and heat transfer, but it decreases the mass transfer rate. Increase in unsteadiness parameter causes the increase in both heat and mass transfer rate whereas it causes a decrease in skin friction. In addition to this, as the chemical reaction parameter increases, it reduces the skin friction and heat transfer, but the mass transfer rate increases.

The trends of dimensionless velocity , temperature , and concentration profiles for the different values of flow parameters are shown graphically in Figures 2–23.

The effect of thermal conductivity parameter on the temperature is shown in Figure 2. It can be noted that the temperature tends to increase as the variable thermal conductivity parameter increases. This is due to the increase in thermal boundary layer thickness; its effect is higher at the boundary layer and decreases as you approach the free stream.

Figure 3 depicts the effect of variable diffusion coefficient parameter on concentration profile. Meanwhile, the diffusion coefficient is a linear function of temperature; it follows that as temperature increases, the diffusion coefficient increases and, consequently, the concentration tends to increase. This is due to the Fick’s law of concentration which shows that the diffusion coefficient is very much depending on the concentration gradient. Thus, as increases, the concentration increases.

Figures 4, 5, and 6 present the typical effects of unsteadiness parameter on the velocity, temperature, and concentration profiles, respectively; it can be noted that an increase in results in the decrease in velocity, temperature, and concentration profiles of the nanofluid. Generally, as increases it causes thickening of the thermal boundary layer. This effect causes the dimensionless velocity, temperature, and concentration to decrease.

The effects of the porous medium parameter on velocity, temperature, and concentration are illustrated in Figures 7–9, respectively. It can be noted from Figure 7 that as increases, the dimensionless velocity decreases; this is because as the tightness of the porous medium parameter increases, the resistance against the flow increases; as a result the fluid velocity decreases and thus the heat is transferred from the hot sheet to the fluid and eventually the temperature and concentration of the fluid increase as shown in Figures 8 and 9.

Figure 10 presents the effects of external magnetic field on the velocity profile. It can be noted that as increases, the fluid velocity declines; this is due to the presence of transverse magnetic fields which causes the emergency of drag force (Lorentz force) opposing the motion of the nanofluid and as a results it retards the flow velocity. Figures 11 and 12 reveal that as increases, it improves the temperature and concentration profile. This is due to higher heat transfer from the hot sheet to the nanofluid and hence the fluid cools the sheet by absorbing its temperature.

Figure 13 displays the effect of concentration Grashof number . It can be noted that an increase in results in the increase in the flow field. Since the concentration Grashof number is the ratio of thermal buoyancy force to the hydrodynamic force and happens on the boundary layer due to variations of concentrations, an increase in thermal buoyancy effect on the nanofluid causes the fluid to cool the hot sheet.

Figure 14 presents the effect of thermal Grashof number . It can be noted that an increase in results in the increase of nanofluid velocity. This is based on the fact that the thermal Grashof number is the ratio of thermal buoyancy force to the hydrodynamic force and happens on the boundary layer due to variations of temperature and thus an increase in thermal buoyancy effect on the nanofluid causes the said fluid to cool the hot sheet.

The effect of Prandtl number on dimensionless velocity is illustrated in Figure 15; it can be noted that as increases, the velocity of the flow field decreases and hence it causes the thermal boundary layer to shrink. It is interesting to note from Figure 16 that as increases, it causes the decrease in temperature of nanofluid; this is due to the fact that is inversely proportional to the thermal diffusion and directly proportional to the momentum diffusivity and thus as increases, it leads to the decrease in thermal diffusion and consequently the temperature and concentration of the fluid decreases.

Figure 17 depicts the effect of Schmidt number on concentration profile. It has been noted that the concentration of the fluid decreases as the Schmidt number increases; this is due to the fact that is directly proportional to the kinematic viscosity and inversely proportional to the mass diffusion coefficient ; thus, as increases, the mass diffusion coefficient decreases and as a result the diffusion foreign species become heavier and normally heavier species have higher .

The effects of chemical reaction parameter on the dimensionless concentration profile are illustrated in Figure 18. It is clear from Figure 18 that as increases, the concentration profile decreases; this means is a slowing agent because it reduces the concentration in the boundary layer and hence at the point very near to the sheet the solute boundary layer turns out to be thinner and increases the mass transfer.

Figure 19 shows the effects of radiative heat flux parameter on the temperature profile. Generally, the presence of chemical reaction results in generations of the radiative heat flux and thus the increase in leads to the increase in the boundary layer thickness and improves the heat transfer rate on the surface and as a result the temperature distribution in the flow region increases as increases.

Figure 20 depicts the effects of inclination angles on the velocity profile. It has been observed that as the inclination angle increases in the anticlockwise from vertical axis, the velocity of nanofluids decreases. This is due to the fact that as the inclination angle increases, it causes both concentration Grashof number and thermal Grashof number to decrease and thus the thermal buoyancy effect on the nanofluid decreases and finally limits the cooling process.

The effects of suction/injection parameter on dimensionless velocity, temperature, and concentration are presented in Figures 21–23. The increase in within the porous retards the fluid velocity and hence it causes the fluid viscosity to increase, as a result the dimensionless temperature and concentration decrease. This is because more fluids are forced to pass through the permeable sheet and as a result the fluids that are very close to the hot sheet suffer decrease in temperature.

5. Conclusion

In this research, a numerical analysis on unsteady MHD flow of nanofluid with variable properties over an inclined stretching sheet in the presence of thermal radiation and chemical reaction is presented. The influence of the nondimensional governing parameters such as suction/injection, unsteadiness, porous medium, magnetic parameter, thermal Grashof number, concentration Grashof number, variable thermal conductivity, variable diffusion coefficient, Prandtl number, thermal radiation, the chemical reaction, Eckert and Schmidt number on the velocity, temperature, concentration fields as well as skin friction, and Nusselt and Sherwood number has been established.

It is found that an increase in variable thermal conductivity parameter results in the increase in temperature of the nanofluid. The increase in variable diffusion coefficient parameter results in the increase in concentration. The increase in either unsteadiness or suction parameter results in the decrease in the velocity, temperature, and concentration. The increase in Schmidt number or chemical reaction parameter results in the decrease in concentration. The increase in Prandtl number results in a decrease in both velocity and temperature. The increase in either concentration or thermal Grashof number results in the increase in velocity. The increase in thermal radiation parameter results in the increase in temperature.

It is further observed that porosity and magnetic parameters have the ability of reducing the nanofluid velocity and enhancing the temperature and concentration profiles and also the duo has the capability of reducing the skin friction coefficient, heat, and mass transfer rates.

Nomenclature

:	Coordinate along the stretching sheet
:	Distance normal to the stretching sheet
:	Initial stretching rate
:	Constants
:	Time
:	Velocity along the − direction
:	Velocity along the − direction
:	Velocity of the stretching sheet
:	Velocity of the mass transfer
:	Force applied along the − axis
:	Temperature of the sheet at the wall
:	Concentration of the fluid at the wall
:	Uniform temperature far from the sheet
:	Uniform concentration far from the sheet
:	Magnetic induction
:	Specific heat at constant pressure
:	Chemical reaction parameter
:	Eckert number
:	Schmidt number
:	Skin friction coefficient
:	Nusselt number
:	Sherwood number
:	Heat flux
:	Mass flux from the sheet
:	Reynolds number
:	Thermal conductivity
:	Molecular diffusivity
:	Temperature of the species
:	Concentration of the species
:	Acceleration due to gravity
:	Radiation heat flux
:	Constant
:	Coefficient of absorption
:	Thermal conductivity of the ambient
:	Diffusion coefficient of the ambient
:	Magnetic parameter
:	Unsteadiness parameter
:	Thermal Grashof number
:	Solutal or concentration Grashof number
:	Prandtl number
:	Thermal Radiation parameter
:	Suction/Injection parameter.

Greek Symbols

:	Inclination angle
:	Constant
:	Stream function
:	Stefan- Boltzmann constant
:	Variable thermal conductivity
:	Variable diffusion coefficient
:	Shear stress
:	Porous medium parameter
:	Delta
:	Permeability
:	Kinematic viscosity
:	Coefficient of viscosity
:	Dimensionless concentration function
:	Coefficient of thermal expansion
:	Volumetric concentration coefficient
:	Dimensionless temperature function
:	Dimensionless space variable
:	Fluid density
:	Electrical conductivity.

Subscripts

:	Free stream condition
:	Properties at the plate.

Data Availability

The data available in the manuscript are parameters values only.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

The authors thank the Nelson Mandela African Institution of Science and Technology, Arusha Technical College, and supervisors for their support.

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Copyright © 2019 Musa Antidius Mjankwi et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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