Numerical Simulations of Magnetic Dipole over a Nonlinear Radiative Eyring–Powell Nanofluid considering Viscous and Ohmic Dissipation Effects

*is research work interprets the influences of magnetic dipole over a radiative Eyring–Powell fluid flow past a stretching sheet while considering the impacts of viscous and ohmic dissipation that produce a quite illustrious effect due to the generated magnetic dipole. *is whole analysis is characterized by the effects of steady, laminar, and incompressible flow. *e highly nonlinear and coupled partial differential equations (PDEs) are remodeled into a system of nonlinear ordinary differential equations (ODEs) by utilizing reliable and nondimensional parameters leading to the momentum, thermal, and concentration equations, that are computationally solved using bvp4c on MATLAB, and “dsolve” command on MAPLE software, in the companionship of boundary conditions. *e physical constraints such as viscous and ohmic dissipation and many other sundry parametric effects are sketched with their ultimate effects on fluid flow. For the sustenance of this research with the prior work and in collaboration with the below mentioned literature review, a comprehensive differentiation is given, which defines the sustainability of the current work. *e Buongiorno nanoliquid model elaborates the thermophoresis and Brownian features that are deliberately scrutinized within the influence of activation energy. Also, the skin friction coefficient, Nusselt number, and Sherwood number are illustrated in tables. *e skin friction coefficient decreases with a rise in the ferromagnetic interaction parameter as well as the Hartmann number, whereas the Nusselt number and Sherwood number show variation for varying parameters. It can be observed that Eyring–Powell fluid intensifies the rate of heat and mass transfer.


Introduction
From the past few years, the fluids eventuated as most significant in almost all the engineering applications, industrial, as well as in technological approaches because of their exclusive property of having no fixed shape and a deforming nature due to external pressure (forces). Also, fluids are further categorized in Newtonian and non-Newtonian fluids having wide petitions in paper production, food factory, paint manufacturing, polymer industry, chemical processing, and profound and boundless applications in manufacturing. e phenomenon of heat transfer has now become a tremendous point to research purposes due to its inflated requirements in many industrial processes such as the cooling process of electronics, lumped system analysis, nuclear reactor insulation, climate control, heat exchangers, architecture, and solar collector. e stretching of a sheet is a significant phenomenon in polymer industry. e fluid flow that occurs due to availability of stretching sheets was firstly explored by Crane [1] and then outstretched by many authors. So far studies about the impacts of the magnetic field over a stretchable sheet show gigantic significance because of its wide petitions in many engineering sites including geophysics, production of paper, to purify crude oil, banishment of plastic sheet, sustained casting, or spinning of fibre due to stretching surface. e outcomes of the external magnetic field in the presence of MHD flow over a stretching sheet were investigated by Pavlov [2] in detail. Gupta and Gupta [3] investigated heat and mass transmission in the presence of the stretching sheet with suction/blowing and presented numerical solution of the boundary layer equation with variation in different parameters. In [4], Rasool et al. studied heat and mass transfer for nonlinear stretching surface using Darcy-Forchheimer relation.
As fluids have common utilization for the phenomenon of heat dissipation as heat transporter, the combined effects of magnetic dipole with fluid is proved influential in constraining the temperature and momentum boundary layers. e turbulent effects in the flow field diminished gradually through magnetic dipole. e effect of magnetic dipole summarizes the restriction of one of the two forms, the closed loop of electric current or couple of poles, when bulk of source diminishes to zero profile, in the case of constant magnetic moment. With an incremented distance from the source, the magnetic source surrounded by the magnetic field looks progressively like the field of magnetic dipole. Kroh and Felderhof [5] scrutinized the impacts of electric and magnetic field on the dynamics of suspension of fluid's particle sustained with electric and/or magnetic dipole effect. e low thermal conductivity is an utmost limitation in the extension of energy efficient heat transfer fluids needed in many industrial applications. Based on the emanated demand in several industries, the devices involving heat exchange be necessitated with compact size, weighing very little and highly efficient. In other words, such devices critically visualized for uttermost thermal efficiency. Quite merely, the conventional fluids such as oil, water, and ethylene glycol exhibit low thermal conductivity. Keeping in mind the property of high thermal conductivity in fluids, there arises a need of time to design such fluids which exhibit sensationally high thermal conductivity. Numerous attempts have been made through many experiments and minichannels, by means of extended surfaces to increase the heat transmission rate, but found quite incredible that a suspension of small quantity of nanoparticles in the conventional fluids enhances the thermal conductivity to a much better extent. Such fluids are called nanofluids. It refers to nanoparticles in base fluid. e name of nanofluid was firstly introduced by Choi and Eastman [6]. In [7], Rasool et al. considered second-grade nanofluid towards a vertical Riga plate for the Buongiorno nanoliquid model. Several models of non-Newtonian fluids are found involving Maxwell, Williamson, Oldroyd-B, Walter-B model, power law model, etc., but these models did not fully describe all the exclusive features of rheological fluids. For more comprehension of non-Newtonian fluids, the Eyring-Powell nanofluid was firstly proposed by Eyring and Powell in 1944.
e Eyring-Powell model is one of the non-Newtonian models developed for scientific research and is very complex in nature. Yet, this model has many advantages over the other non-Newtonian formulations, including simplicity, easy to compute, and physical robustness. Following are the two main properties of Eyring-Powell fluid that make it unique and significant over some other non-Newtonian models.
(i) It has been derived from kinetic theory of liquids instead of empirical relation (ii) e model easily reduced to a Newtonian model, just for higher and lower shear rates  (a mixture of cement or clay with water), tooth paste,  human blood, etc. e model belongs to the fluid model  containing three constants. is model is competent to exhibit a nonzero viscosity in the surrounded domain at the surface as well as in the ambient fluid discussed in [8].
Viscous dissipation is a phenomenon to endure the work done mutated into heat, a conversion of kinetic into internal energy. e work is done by the fluid on juxtapose layers in the companionship of shear force. e propensity of viscous dissipation effects on the temperature profile will be liable to influence the heat transfer. Consequently, during the high extrusion in polymer processes or especially in blowing existence, the temperature distribution enhanced. In [9], Healy et al. worked for the successive progress of the viscous dissipation function as a concept of velocity gradient where the whole approximation is based on power loss in fluid dynamics. So far, a lot of related work had been done in this regard. Ohmic dissipation of heat is beneficial in heating the liquid edibles accommodating large particulates. For instance, soups, cutting sliced fruits, other heat sensitive fluids, and also helpful in the treatment of proteinaceous foods. Potentially, it has applications in blanching, discerning of starch gelatinization, etc. e accommodation of minimum energy to initiate the chemical reaction is because sometimes, during the chemical reaction, the molecules collaborate with adequate energy. e debasement of bonds is amenable by two significant energies, the kinetic and potential. At this particular time, the loss in kinetic energy and unsustained collisions requires a compatible amount of energy to activate the molecules for the reaction, and this leads to the concept of activation energy. is activation energy is vigorously used in the field of biochemistry, geothermal industries, hydrodynamics, etc. In [10], Mazzotti et al. explored the work for thermal dependency of viscosity sufficiently explained by activation energy and Arrhenius model along with the distinctive function of the concentration volume fraction. In [11], Saghir and Eslamian highlighted the effects of net transportation of heat by using the concept of activation energy of self-diffusion, and the obtained solution were more accurate as compared to the solutions we get while approximating it by the idea activation energy of viscous flow. Babu and Sathian [12] probed to analyze water accompanying activation energy through carbon nanotubes. Javed et al. [13] explored his work for the boundary layer (BL) flow using non-Newtonian characterized fluid in the presence activation energy over a stretching sheet. See regarding references to further study on activation energy and chemical reaction. ermal radiation comes out when technological methodologies are enacted at high value of temperature. It is the emanation of electromagnetic waves from the corresponding fluid at a temperature that is higher than that of absolute zero. So, when there occur small changes in the temperature gradient, it is advantageous to use the concept of linear thermal radiation. But if there are disastrous changes occur in the temperature gradient, then the nonlinear thermal radiation is useful to consider. For example, the case of rocket propulsion and nuclear reactor. Hayat et al. [14] had a detailed work on 3-dimensional BL flow of viscoelastic nanofluid using nonlinear thermal radiation, and the condition for the requirement of zero mass flux was executed. e sensations associated with the chemical reaction have prodigious contributions in many chemicals-based industries. Many researchers came in market and gave their tremendous efforts on the impacts of the chemical reactions on different problems. Narayana and Babu [15] explored that how non-Newtonian fluids are influenced by the chemical reaction for a stretching sheet. Related reviews for this analysis are referred [16][17][18][19][20][21] for further knowledge. In [22], Azhar et al. discussed the effects of viscous dissipation influenced by chemical reaction and considered the stagnation point flow. In [23], Jabeen et al. gave the idea about influencing MHD flow in porous media, and the solution were obtained by using DTM (differential transformation method) and VIM (variational iteration method) approach. Similar results about magnetic dipole, viscous dissipation, and radiation are cited for further study in below references [24][25][26][27][28][29][30].
Motivated by the aforesaid literature review, this current pattern has a superficial role of Eyring-Powell non-Newtonian fluid over the stretching surface because of its wide petitions in the production of electronic devices and many medical apparatus, glass fibre, and filaments. Our model basically describes the exceptional viscous and ohmic dissipation effects subjected to magnetic dipole of chemically reacting fluid so this research work is quite advantageous in the field of paper production and manufacturing of plastic. While, in areas of quantum mechanics, aerospace engineering, and space technology, the role of this work is useful due to magnetic dipole. e surface (sheet) is stretchable linearly. No doubt, local similarity transformations with nondimensional expressions are used to transmit the highly nonlinear coupled governing equations into simple ODEs and are then resolved. e solutions are extracted on the basis of numerical strategy by using the reliable algorithm of bvp4c on MATLAB and MAPLE dsolve, and then, the influences of different active parameters on velocity, temperature, and concentration profiles are contemplated, and ultimately, the outcomes are graphically scrutinized. e perspective solutions are cataloged and tabulated in detail. e present results are compared with published works in open literature and found a good agreement.

Constitutive Relations
While considering a non-Newtonian Eyring-Powell fluid model, the basic constituent relation is defined as [24] T � − pI + Q, where In abovementioned expressions, T is Cauchy stress tensor, p represents pressure, I represents identity tensor, Q is the extrastress tensor, μ describes dynamic viscosity, A 1 is the first Rivilin-Ericksen tensor, c is shear rate viscosity, β * and C * are the material constants, and V is the described velocity field. Now, up to second-order approximation of sinh − 1 function leads the expression towards After the simplification of boundary layer approximation, the flow equation for the Eyring-Powell fluid model now takes the form:

Model Formulation
e modeling is about a two-dimensional steady flow of incompressible non-Newtonian (Eyring-Powell) liquid within the influence of the applied magnetic field. e flow region is basically confined to y > 0. To magnetize the liquid, a magnetic dipole having adequate intensity is placed over a stretching sheet in which x-axis lies horizontally to give rise a magnetic field whereas the y-axis is taken perpendicularly to the stretching surface. e region of flow is exposed by a uniform transverse magnetic field � (0, B o , 0) and a uniform electric field � (0, 0, − E o ) given, which are sufficiently applied across the stretching sheet. From Maxwell's equation, it is known that Δ · B � 0 and Δ · E � 0. So, the fluid is saturated with the magnetic field due to the presence of magnetic dipole. e stretching velocity is u w � ax, and the perspective sheet is taken linearly stretchable to generate the flow, where "a" is greater than zero and is the stretching rate, as shown in the schematic demonstration of the flow model in Figure 1. Further, for liquid magnetization, the magnetic dipole is positioned in such a way that its distance below xaxis is given by "c" and center on y-axis. e temperature at Mathematical Problems in Engineering 3 the stretching surface is T w .
e Buongiorno model is accounted. e ramifications of activation energy and non-Linear thermal radiation are also taken into consideration. For this flow model and in regard of aforesaid assumptions, the respective governing equations are [16,17,24] zu zx where kinematic consistency is represented by ] � (μ/ρ), ρ f is the base liquid density, σ is the representation of electrical conductivity, H is the imposed magnetic field in the perpendicular direction along y − axis, M represents the magnetization factor, fluid's temperature is given by T, specific heat capacity of the nanoparticle material is denoted by c p , C is the nanoparticle fluid concentration, D B and D T are the Brownian diffusion coefficient and thermophoretic diffusion coefficient, E a is denoted as the activation energy, β * and C * are the material constants, κ is the Boltzmann constant, and k 2 r is the chemical reaction rate constant. e surface coordinates both perpendicular and parallel are y and x, and the velocity components in the direction of x and y are u and v. e correlated boundary conditions for the above PDEs have been taken as In boundary conditions, the stretching rate of the sheet is represented by "a," T w denotes the hot fluid temperature, while T ∞ and C ∞ represent the ambient temperature and ambient concentration, respectively. It can be seen here that two forces constitute same magnitude but opposite orientations are employed to the sheet, while the origin is kept constant. e boundary condition u| y�0 � ax depicts the stretching velocity whereas v| y�0 � 0 demonstrates that the surface is impermeable, exhibiting no suction/injection. Further, u| y⟶∞ ⟶ 0 physically describes that the freestream velocity is zero, while T| y⟶∞ ⟶ T ∞ signifies the ambient fluid temperature and C| y⟶∞ ⟶ C ∞ reflects the ambient fluid concentration. e liquid flow is influenced by the magnetic field that is subjected to the concept of magnetic dipole whose scalar potential is Φ * . us, the expression for the magnetic scalar potential, say Φ * , is expressed as where c * basically points out the strength of magnetic dipole. For this flow, we considered that the field of magnetic force is conservative. We know that any conservative force can be expressed as a scalar of any potential function. So, in this case, the scalar potential function is represented by Φ * . e components of the magnetic field along with its magnitude are given by H x and H y : By expanding using Taylor's configuration for x up to order 2, then from equation (13), one can get these two forms: e variation of magnetization (M) via temperature can be determined by the utilization of below expression, that is, Now, the stream function that has been introduced and assumed to satisfy the continuity equation is given below. For the conversion of (6)-(8) into the dimensionless form, the following appropriate similarity transformation has been applied: where ψ depicts the stream function, the respective (η, ζ) represents the dimensionless parameters, and θ(η) and ϕ(η) are the expressions for thermal and concentration distribution along with the velocity components. By using transformation given in (16), our above governing model (6)-(8) has now turned into a dimensionless system and exhibits the perfect ODEs that are Mathematical Problems in Engineering While transforming the conventional model into a frame of ODEs, following parameters are introduced during this transformation to have such formulation: where prime (′) denotes the differentiation with respect to η and the abovementioned parameter represents the Prandtl number, ferromagnetic interaction parameter, thermal radiation variable, temperature difference variable, dimensionless difference parameter, viscous dissipation parameter, thermophoretic parameter, Brownian motion parameter, temperature ratio variable, Schmidt number, chemical reaction rate constant, activation energy, fluid parameters (ε, δ), Hartmann number, and local electric parameter, respectively. And, the boundary conditions at (η � 0 and η ⟶ ∞) regarding the ODE's (6)-(8) get the form:

Physical Quantities (Velocity, Thermal Gradient, and Solutal Gradient)
In practical interest, the most significant physical quantities are C fx , Nu x , and Sh x which denote the coefficient of local skin friction, coefficient of local rate of heat transfer, and mass transfer rate coefficient, respectively. e mathematical formulation of the surface drag coefficient (C fx ), thermal gradient (Nu x ), and solutal gradient (Sh x ) is defined as where τ w , q w , and q m are the representation of wall shear stress, heat flux, and mass flux, respectively, at the wall, i.e., at y � 0, and are described as e nondimensionalization of the surface drag coefficient which is also the velocity gradient C fx , thermal gradient Nu x , and solutal gradient Sh x using the similarity transformations is given as where f ″ (0) depicts the nondimensional wall shear parameter, θ ′ (0) represents the nondimensional rate of heat transfer at sheet, and ϕ ′ (0) depicts nondimensionalized rate of mass transfer where the expression Re x � (ax 2 /]) is for local Reynolds number. It is more obvious that the field of flow is primarily affected by the parameter of ferromagnetic interaction (β).

Numerical Scheme
e above highly nonlinear scheme is transformed to the boundary value problem (BVP) settled in equations (17)- (19) in the companionship of pertinent boundary conditions given in (21). e resulting system is scrutinized on numerical basis by the implementation of the bvp4c scheme using computational software MATLAB.
Prior to initiate the numerical simulation, firstly we remould the higher order BVP into first order (IVP). Such reformation of BVP into IVP is localized on the basis of some restricted values as (η ⟶ ∞ ) for a restricted domain boundary condition say (η ∞ � 5). For this, one can introduce the new settlement of dependent specified variables as follows: where where along with the boundary conditions: e abovementioned IVP will be scrutinized using the numerical approach by the bvp4c method on MATLAB. In order to attain the approximate solution, the domain of the observed problem has been taken within the interval as [0, η ∞ ], where η ∞ defines a pertinent finite positive number of real line, and we take it as 5 during our implementation. Moreover, mesh resolution is created in grid continuation and tolerance of relative error in this method which is particularized as 10 − 7 .

Results and Discussion
In this article, the main focus of this subsequent discussion is to tackle the physical and graphical features. e miscellaneous parameters in the respective field of flow are taken into account. e equations involved in this flow are a highly nonlinear coupled set of ODEs experiencing the boundary conditions as an outcome of transformation of PDEs. e system of third-order ODEs is then interpreted by means of the bvp4c scheme using MATLAB with given comparison using MAPLE dsolve. en, the ramifications under the varying physical parameters with pertinent values of ferrohydrodynamic interaction (β), Prandtl number (Pr), Brownian motion Mathematical Problems in Engineering parameter (Nb), thermophoresis parameter (Nt), electric parameter E 1 , Schmidt number (Sc), temperature ratio variable (θ w ), thermal radiation parameter (N), activation energy (E), Eckert number (Ec), chemical reaction rate constant (σ), temperature difference parameter (δ 1 ), Sherwood number (Sh) against the axial velocity f ′ (η), thermal field θ(η), and the concentration profile ϕ(η) are explored. e present research work is numerically computed and tabulated for velocity, thermal, and solutal gradient and then graphically scrutinized in detail. A parallel comparison is given for both the methods to demonstrate that bvp4c casts a less computational cost and gives more accuracy of numerical computation. is method is an effective solver, with an approach towards the increasing convergence criteria. e boundary conditions of the BVP (boundary value problem) and the algorithm that is handled in bvp4c typically make it a direct method because the final equation to solve on the defined domain of interval is algebraic. On the contrary, ds olve take less time to execute and casts less computational cost. In ds olve MAPLE, both initial and BVP can be numerically computed. For a system input, the type of problem is automatically recognized. As both are numerical methods, the numerical method always works with iteration. Such methods are easy to compute. When the analytical solution does not exist to solve a system, then numerical solution is preferred. is section includes the physical interpretation of physical parameters that cast impact on the flow field by variation. e outcomes of this research work have found a good agreement with the prior published works which indicates the sustainability of the abovementioned research studies. Table 1 highlights the comparative outcomes of velocity gradient C f (Re x ) (1/2) along with the analysis given in [13,24], showing a good agreement with prior research studies. Table 2 shows the effects of C f (Re x ) (1/2) for different values of ε, δ, Ha, E1, and β. It was observed that rising values of δ, Ha, and β decrease the skin friction coefficient. Besides this, for larger ε and E1 parameters, C f (Re x ) (1/2) reveals an increment trend, whereas in Table 3, the outcomes elaborate the parametric effects of Pr, N, θ w , Ec, Ha, Nb, and Nt against the thermal gradient Nu(Re x ) − (1/2) . Here, larger estimation in Pr, N, and θ w parameters yields the ascending profile for Nu(Re x ) − (1/2) , while for higher values of Ec, Ha, Nb, and Nt parameters, Nu(Re x ) − (1/2) reveals a descending trend. Table 4 is scrutinized about the − Sh(Re x ) − (1/2) outcomes for varying values of σ, δ 1 , Sc, and Nb, and the results evaluated that, for increase in these parameters, the Sherwood number rises, while for higher E, Ha, β, and Nt parameters, the solutal gradient falls down gradually.
So far, the respective graphical approach is considered, and Figure 2 depicts the graphical scrutinization of velocity profile versus η for different values of local electric field parameter E 1 . It is observed that the velocity profile exhibits an increase in the boundary layer thickness with uplifting values of electric parameter E 1 but more significantly, a little bit away from the stretching sheet. e overall analysis highlighted the theme that the impact cast by E 1 is basically to shift the streamlines little away from the stretchable boundary because the Lorentz force rises due to effect of the electric field and acts as an accelerating force in decreasing the frictional resistance effects. Figure 3 illustrates the impact of β against the velocity profile f ′ (η). e decaying trend emerging via larger β implies that the fluid motion is the decreasing function of the β factor. In physical simulation, an uplift in the values of β causes to enhance the resistive force (called the Lorentz force) in fluid flow that slows down the motion of fluid, as the viscosity becomes more concentrated for larger values of β that ultimately declines the velocity profile. As expected, f ′ (η) diminishes via larger β.
In Figure 4, the Hartmann number (Ha) is now to indicated a decreasing behaviour for the velocity profile in the boundary layer that comes up with the effect in thinning the boundary layer thickness. Figure 5 indicates the effects of (Ha) on the thermal profile. Temperature distribution increases with continual rise in (Ha) number.
e figure gives the result that the uniform transverse magnetic field participates in thickening the thermal boundary layer. is concept comes from the fact that the applied uniform transverse magnetic field gives rise to a body force such as Lorentz force which causes an opposing reaction in the motion, thereby enhancing the temperature profile. Figure 6 demonstrates the impact of increasing values of E 1 parameter against the temperature profile. As with the continuous rising in E 1 parametric values, the thermal graph shows a decline behaviour. Figure 7 proclaims the stimulus of ferrohydrodynamic interaction variable (β) on θ(η). One can observe that, with an intensification of β, θ(η) is an enhancing function of β.
rough larger β approximations, the resistive force upsurges due to which the fluid movement faces high resistance during its flow. As a result, this friction converts the valuable mechanical energy into heat energy that augments the temperature. Hence, θ(η) rises for larger β which is evident in Figure 3. Now, Figure 8 poses to display the behaviour of θ(η) due to discrete values of (Pr). e increasing trend of (Pr) delineates the thermal graph. In the physical sense, since the Prandtl Number is dimensionless and defines as a relation (ratio) of molecular diffusivity over thermal diffusivity, so (Pr) and thermal diffusivity are inversely inter-related, noticing the reduction in the proficiency of energy transportation. Also, the thickness of the boundary layer compressed just about to wall. e increment in (Pr) parameter drops the thermal diffusivity and eventually makes the fluids temperature to fall down.
Curves of θ(η) examined through Brownian motion parameter (Nb) for absolute variation are elaborated in Figure 9. e graph scrutinizes that increase in (Nb) typically enhances the temperature profile. e description is quite reliable. As the (Nb) parameter is in accordance with the concentration gradient when giving the variation to this parameter results in boosting the thermal energy of fluid, it ultimately brings the temperature profile up. It can also be observed that, for larger (Nb), the collision between the 8 Mathematical Problems in Engineering nano-sized particles is augmented in flow that yields convection due to which the temperature enhances in a definite sense. Figure 10 is plotted to display the ramifications of thermophoresis parameter (Nt) over θ(η) for discrete values. e graph illustrates that rising the (Nt) parameter intensifies the temperature field in the zone of boundary layer aligned (horizontal) to the wall. In fact, the (Nt) parameter is correlated with the temperature gradient. is parameter tends to transport the fluid particles with its positive variation from a region of higher energy level to the colder one and intensifies the fluid temperature in the flow regime. One can say that, while uplifting its parametric values, it increases the thermal energy responsible for augmentation in the temperature field. Figure 11 is designed to demonstrate the impacts of temperature ratio variable (θ w ) against θ(η). Here, thermal layer and θ(η) are in correspondence as well as θ w upsurges. It physically elaborates that the outcome of uplift in this parameter rises the surface temperature T w and ultimately leads to more heat transportation. erefore, rise in θ w results in intensification of the temperature field.
Curves that occur in Figure 12 are designed to interpret the role of the thermal radiation parameter (N) versus θ(η).
is figure reveals that, for higher estimation of (N) parameter, it escalates the thermal profile. e fact is the mean absorption coefficient (δ * ) that tends to decay as (N) parameter accelerates. As a result, the diffusion flux comes into being, observing that the radiation parameter has a momentous supremacy over this profile. Figure 13 highlights the characteristics of the Eckert Number (Ec) against θ(η).
e major aspect of this graphical approach is to signify that the thermal layer Table 1: Comparative outcomes of C f (Re x ) (1/2) with Ref. [13] and Ref. [24] when β � 0.   intercorrelated with θ(η); both depict the ascendancy for larger variation in the (Ec) profile. Due to rise in (Ec), the thermal energy in fluid is accumulated that leads to friction force that inflated this thermal graph.
In Figure 14, the graphical scheme exhibits the effect of the Brownian motion parameter (Nb) against ϕ(η). It can be seen that, for higher extension in (Nb) values, the associated thermal layer along with the ϕ(η) profile deteriorates sharply. As, for higher Nb, collision among nanoparticles rises that tends to move them in irregular manner, which results in diminishing the corresponding solutal layer. Figure 15 describes the characteristics of the concentration field affected via the thermophoresis parameter (Nt). Significantly, the fluid's thermal conductivity reinforces because of the existence of nanoparticles for greater (Nt).
Curves subjected to Figure 16 explore the impacts of the Schmidt Number (Sc) over ϕ(η). e positive increment in (Sc) profile causes permanent diminution the concentration field. Briefly, Sc and momentum diffusivity factor (D B ) are   inversely coupled. So, higher estimation in (Sc) intensively declines the solutal layer and so does the profile. Figure 17 highlights the physical nature and behaviour of the activation energy parameter (E) within the variational frame against ϕ(η) nanofluid concentration. One can detect that intensification of (E) parameter enhances the concentration profile. On the base of physical sense, for greater (E) parametric values delineating the basic Arrhenius activation energy factor, it results in boosting up the rate of chemical reaction. is enhancement in the chemical reaction rate intensifies ϕ(η). Figure 18 signifies the aspects caused by the discrete variation in the temperature difference parameter (δ 1 ) over ϕ(η). Focusing the graph demonstrates that ϕ(η) reduced gradually until it vanishes. e physical significance is the escalation in the destructive chemical reaction rate. Figure 19 reveals the outcomes of the chemical reaction rate (σ) parameter that tells the physical interpretation of vanishing the concentration profile as the parametric value varies. By increasing the values of ((σ)), more species are consumed so the rate of chemical reaction increases which causes to decline the concentration profile. Figure 20 demonstrates the impact, due to fluctuating values of β on ϕ(η), and exhibits that, with uplifting values of β, there occurs an increment in the concentration profile. Because, for increase in parameter β, resistive force comes into being that causes an increase in the concentration of nanoparticles in the fluid flow due to which the energy transportation increases and ultimately increases the concentration profile. Figure 21 poses the effect of the Ha number on the concentration profile. e figure exhibits that, with higher values of the Ha parameter, the concentration profile increases because of enhancement in concentration boundary layer thickness as the Lorentz force causes an opposing reaction in the motion of nanoparticles and enhances the concentration of particle, thereby enhancing the concentration profile.

Concluding Remarks
is research work summarizes the analysis about viscous and ohmic dissipation effects through a stretchable sheet. Chemical reactions are under consideration. e analysis is deliberately performed in the presence of magnetic dipole. e heat transfer characteristics causes the generation of heat in the presence of magnetic dipole where viscous and ohmic dissipation aspects are reported. Heat generation aspect is preserved. e impact of nonlinear thermal radiation in the flow of ferromagnetic Eyring-Powell nanofluid (a lot of its application involving paper production, glass filaments, etc.) under the magnetic field persuaded by the dipole effects is described in the orientation of the model just because of its wide applications in areas of space technology and aerospace engineering. e aim of this research work is to lessen the drag friction and intensify the rate of heat and mass transfer. e key findings of aforementioned analysis are itemized as (i) An intensification of β, which ultimately delineates the nanoliquid velocity profile f′(η). (ii) ermal profile θ(η) of the nanofluid during flow and its corresponding layer thickness enhances via progressive estimation in β, N, Ec, θ w , c, N b , N t , and E 1 . It can be noted that, with increase in thermal radiation, temperature tends to rise. (iii) Increasing Pr causes reduction in the profile θ(η).
is scenario is perceived because of weaker diffusivity subject to higher Pr.

Data Availability
e data used to support the findings of the study are included within the article.

Additional Points
(i) e effects of viscous and ohmic dissipation under the influence of magnetic dipole for Eyring-Powell nanofluid are studied. (ii) e Buongiorno model is taken into account while considering the stretchable surface. (iii) e impacts of thermal radiation, thermophoresis, and Brownian movement parameters are observed for the respective nanofluid. (iv) e varying Schmidt number and chemical reaction lessen the thickness of concentration profile. (v) Graphical behavior is presented for each of the affecting physical parameter with tabular description of the skin friction coefficient, Nusselt number, and Sherwood number.

Conflicts of Interest
e authors declare that they have no conflicts of interest.