Analysis of second grade nanofluid flow confined by lubricated disk with bioconvection

Thermal mechanism of non-Newtonian nanofluid coated by lubricated power law material has been theoretically worked out. The slip interaction constraints have been proposed for inspecting the thermal transport. The concept of microorganism is utilized to achieve the stabilization of the suspension of nanoparticles. The rheological constraints of nonlinear model are observed by second grade fluid. The flow phenomenon is governed by stagnation point flow. The second-grade (SG) axisymmetric bio-convective nanofluid flow across a moving surface is considered. The flow equations are simplified by the implementation of compatible similarity transformations. The resulting system is solved numerically and analytically by using a hybrid homotopy technique. With the use of a graph and tabular data, the importance of influencing parameters in relation to the velocity field, motile density microorganism’s, temperature and concentration profiles is investigated. The thermal profile is observed to be lowering with higher Prandtl number values. There is a noticeable drop in concentration and thermal profiles against higher viscoelastic parameter values. The microorganism profile is lower in the presence of bio-convected Lewis number. Moving from Newtonian fluid to non-Newtonian fluid, a decrease in motile organism and Nusselt number.


Introduction
The popularity of non-Newtonian fluids among modern scientists, engineers and computer scientists is well known.There are numerous engineering uses for non-Newtonian fluids, industrial operations, including lubrication, plastics processing, mining, the chemical industry and medicinal applications.These liquids can be divided into three categories: integral, rate and differential types.The non-Newtonian fluids differentially sorted known as viscoelastic type fluids.They differ from other fluids in several ways by their higher-order equations for the viscous materials as opposed to the Navier and Stokes formulas.To get a distinctive response, it is necessary to add a few more boundary criteria.Rajagopal 1,2 reported the SG fluid problem and executed that SG is the most straightforward model of non-Newtonian fluids.An analytical solution of SG fluid flow is anticipated by Sahoo and Labropulu. 3he term nanofluid refers to suspensions containing nano-sized particles (such as silver, gold, aluminum, copper, diamond and so on) and conventional base fluid.It has been experimentally discovered that the ordinary heat transmission fluids have lower thermal conductance.Therefore, a variety of experiments have been conducted to augment their thermal efficacy.The flow geometry is altered and particles of various sizes such as micro, milli and others are used.Are inserted but the desired results were not obtained.Choi and Eastman 4 considered the nano-size particles in the base liquid and discovered that the resulting fluid has higher thermal features.After that, Brownian's movement and thermophoretic force influences of nano-particles strengthened the concept of dissipation of heat, exchange of heat in fundamental fluid, in engines of hybrid power and powerful healthcare like treat through chemicals. 5Khan and Pop 6 demonstrated the stretched boundary-driven nanofluid flow induced by the movement of surface.They addressed that the Brownian's movement and thermophoretic force have influential impacts on the thermal feature of materials.Khan et al. 7 investigated the non-aligned electrically conducted stagnation point nanofluid under Brownian movement and thermophoretic influences.Krishna et al. 8 investigated the radiated magnetized Casson hybrid nanomaterial induced by the vertical porous surface.Madhu et al. 9 examined the time-dependent Maxwell nanomaterial flow with the consideration of magnetohydrodynamics and thermal radiation.The effectiveness of Hall, Joule, and Soret effects in magnetic mixed convected flow is illustrated by Krishna et al. 10 The similar treatment of magnetized Newtonian fluid flowing over the surface is addressed by Chamkha and Khaled. 11Gorla and Chamkha 12 conducted an analysis of non-isothermal flow through porous medium.Chamkha and Rashad 13 executed the dynamics of magnetohydrodynamic mixed convection flow of Newtonian fluid.Their study centered on a rotating vertical cone and considered factors such as chemical reactions as well as the Soret and Dufour effects.Khan et al. 14 conducted an assessment of irreversibility in the Casson nanofluid flow when there is leading-edge accretion or ablation.Khan et al. 15 addressed the mechanical characteristics of Maxwell nanofluid within a dynamic system.
The microorganism includes flagella or bacteria which possess higher density as comparative to water and on average, they traveled opposite to direction of gravity.The microorganisms gathering develop the suspension higher layer denser as comparison to below layer which creates an unstable distribution of density.Consequently, the convection instabilities taken the place and generated the convection patterns.This random and spontaneous movement of microorganisms' pattern in the suspension is famous as bioconvection.
The theme of investigation of microorganisms' swimming pattern in liquids heavier than water is due to their connectivity with commercial, ecological, and industrial appliances include ethanol, ecological fuels, fuel cells, and fertilizers.The global warming and weather changing circumstances linked with the emission of carbon-dioxide emission involved an appropriate mechanism to cloister carbon from the surroundings.Microalgae system is generally implemented to pull out the carbon-dioxide from industrial exhausts through system of flue gas combustion.The hydromagnetized bioconvected water-based nanomaterial flow having motile microorganisms over vertical porous surface is addressed by Mutuku and Makinde. 16Raees et al. 17 reported the time-dependent bioconvected nanofluid through a channel with wall contraction.The transportation of biofluid using both gyrotactic microorganism and nanoparticles is addressed by Be´g et al. 18 Giri et al. 19 executed the nature of Stefan blowing on magneto bioconvected nanomaterial flow.The thermal slip behavior on SG bioconvection flow under gyrotactic microorganism is elaborated by Zuhra et al. 20 Siddiqa et al. 21analyzed the bioconvection viscous nanomaterial flow along a wavy cone.Zuhra et al. 20 conducted a study focused on simulating bioconvection in a suspension comprising a second-grade with nanoparticles and gyrotactic microorganisms.Meanwhile, Khan et al. 22 investigated the dynamic pathways associated with bioconvection within a thermally activated rotating system.
Lubricants are used for a variety of purposes aside from industrial applications include cooking, humanbio appliances, ultrasound and clinical assessments etc.It is primarily used to decrease friction which contributed the most efficient operational mechanism in industries.The stagnation point (SP) flows attached to lubricated films are widely studied because of their applications in the design and cooling industries.Regardless their potential application in the cooling industry and design, the SP flows past a lubricated surface have received little attention.Joseph 23 assumed a thin lubricated layer over solid surface to determine an analytical slip-boundary condition.In his research, he pointed out that the gradient of velocity at the interface is directly linked to the velocity square segment.Solbakken et al. 24 performed the numerical simulation to address the influences of lubrication on the channel flow under interfacial conditions.The slip conditions influences on rotatory lubricated flow of non-Newtonian fluid were executed by Andersson and Rousselet. 25][29][30][31][32] Taking into account the previously conducted studies, the primary objective of the current research model is to investigate the control dynamic of second-grade (SG) nanoparticles on a lubricated surface, employing the concept of microorganisms to attain the stabilization of the nanoparticle suspension.It's worth noting that, as of now, no prior studies have been carried out in this particular context.Current investigation deals with the thermal mechanism of SG nanofluid due to lubricated surface theoretically.Summering the different aspect of work as follows: Ø The energy and mass transportation of SG nanofluid is studied due to stagnation point flow of stretched surface.Ø The thin layer of surface is coated with lubricated power law material.Ø The relation for bioconvective model is elaborated to observe insight dynamic of microorganism phenomenon.Ø The thermal interaction of slip is proposed near the convectively heated surface.[35]

Modeling
We considered 2D bioconvection SP flow of SG nanofluid over lubricated surface.A thin layer having variable thickness h(r) is produced on the disk by the power law lubricant from a point source at the origin as shown in Figure 1.
Consequently, the constant rate of flow of lubricant is established by: The governed mathematical model is illustrated as: + 2w r + ∂u ∂z + u r In above u, v, w ð Þare velocity component along coordinate axis.T within boundary layer and by T ' at free stream, C is concentration, n Ã be the microorganism, r depicts the density, p is the pressure, n is the kinematic viscosity a 1 is the material parameter of SG fluid, and maximum cell swimming indicates by w c , D B is the Brownian diffusion coefficient, D T is the diffusion thermophoresis coefficient.We denoted the heat capacity ratio of nanoparticles and base fluid by t.
The power-law lubricant is presented in the region 0\z\h r ð Þ, while the SG fluid filled the region h(r)\z\1: The typical wall-based no-slip situation is Considering that the lubricating layer has no axial velocity, we have: It is assumed that the SG fluid and power-law lubricant interacted at an interface region where the velocities and shear stresses for both fluids are constant.At z = h(r), the shear stress is continuous as where the consistency index is k and the power law index is n.The radial component U of lubricant velocity varies linearly as: where the radial component of velocity for both fluids at the interface is denoted by the symbol Û(r).When equation ( 8) is used in equation ( 1), the layer thickness resulted in the form: Equation ( 7) thus becomes: Furthermore, the fluid-fluid interface's continuous axial velocity provides: The interface pressure is 11 : The free-stream conditions are described as: The similarity variables are described as 15 : Invoking these transformation equation, the continuity equation ( 2) is identically satisfied (3)-( 7) takes the form: Subject to boundary conditions.

Solution development
By using initial value problem we can convert the boundary value problem and by using Na, 36 into initial value problem by considering conditions which are missing.
g 000 + 2gf 00 + 2fg 00 À 2f 0 g 0 + K 2f 00 g 00 + 2f 0 g 000 + 2f 000 g 0 À 2fg 0000 À 2f Subject to the lubricated conditions The computations of above equations cannot be achieved through general integration schemes due to the compatibility of equations and conditions.For this, the numerical scheme is adopted in which ' is replaced with z ' and subintervals are used to divide the domain into 0\z\z ' represented by H i such that X H i = z ' , i = 1, 2, 3:::::: Each sub-interval is addressed by i Subject to the condition as The initial value problems ( 35)-( 53) are now solved using the homotopy analysis procedure [37][38][39] in every subinterval.The numerical values at ith sub-interval are treated as initial conditions for (i + 1)th subinterval for HAM solution.

Discussion of the obtained solution
With the help of the hybrid homotopy analysis method using Mathematica, the problem of SP flow of SG nanofluid confined by a lubricated disk with bioconvection is computed.Figure 2(a) to (d) illustrates the variation slip parameter l for velocity, temperature, concentration and microorganism profiles.The influence of the slip parameter on the velocity field f 0 transitioning from full slip to no-slip conditions is illustrated in Figure 2(a).This figure elucidates that in the case of complete slip l !0, the impact of the free stream velocity on the flow is counteracted by the slip occurring at the surface.As the slip parameter is augmented, the velocity component f 0 rises, leading to a reduction in the boundary layer thickness.The temperature field for slip parameter is pictured in Figure 2(b).We have noticed that by increasing slip parameter u z ð Þ decreases.Physically, we noted that by increasing slip the fluid speed also increases but the temperature at wall decreases.The same variations can be observed for concentration as well as microorganism profiles f z ð Þ and c z ð Þ that can be seen from Figure 2(c) and (d).By increasing slip parameters the species of concentration as well as density of motile organism also increases.Figure 2(a) to (d) highlighted the significance of second grade parameter K on thermal profile, concentration and microorganism fields.Figure 3(a) illustrates the impact of the viscoelastic fluid parameter on the velocity component f 0 .It demonstrates that as the viscoelastic parameter is increased, the velocity increases while the boundary layer thickness decreases.When the parameter K is large, the fluid exhibits reduced viscosity, leading to lower fluid resistance and an increase in fluid velocity.The effect of K on u z ð Þ for different values is described by Figure 3(b).we have noticed the fall in temperature for larger value of K.This decrease in temperature profile for large K becomes more obvious if we lubricate the surface.Same observations are seen for concentration and microorganism fields f z ð Þ and c z ð Þ from Figure 3(c) and (d) but decrease is more obvious in case of concentration species.The trends of n on u z ð Þ, f z ð Þ and c z ð Þ are described by Figure 4(a) to (c).In Figure 4(a), the changes in temperature u z ð Þ for different values of n are described.A significant decrease in temperature for larger n values is achieved.This figure also describes that although the boundary layer is more necessary compared to the shearing thinning lubricant for shear thickening.We observed the same variations for concentration profile and microorganism are seen as one can see through Figure 4(b) and (c) and noticed that this fluctuation is more obvious than temperature distribution.Figure 5 is sketched for the purpose of seeing the importance of Prandtl Pr on the temperature distribution for partial slip case.It is clearly noticed from the figure that for larger Pr the temperature and thermal thickness of layer are more significant.It is noticed that thermal diffusivity behaves inversely for larger values of Prandtl number and it also help in the decrease in temperature and boundary layer thickness.It is clearly observed that the rise in temperature for larger value of Prandtl number is more prominent for partial slip l = 1 than no-slip l !'.   very prominently on lubricated surface but, Nt against increase more obvious on rough surface.Figure 9        see that when the bioconvection Reyleigh number increases, the skin friction coefficient decreases.Growing microorganism increases both the Sherwood and local Nusselt populations.Tables 4 and 5 have been created to facilitate a comparison the results obtained in this study and those previously published.This comparison is conducted for both no-slip and slip cases, specifically for viscous fluid scenarios.Notably, the current hybrid solution demonstrates an exact match with the previously published limiting results, confirming the accuracy and reliability of findings.

Conclusions
Bioconvective SG nanofluid flow over lubricated surface is presented in this analysis.It has been investigated how important thermophoresis and Brownian motion are in slip impact.With the proper boundary constraints, partial differential equations are used to frame the issue.These equations are then similarly converted into ordinary differential equations (ODEs).The dimensionless ODE system was then numerically and analytically solved by HHAM.The primary take aways from the current analysis are The slip parameter reduces the free stream velocity profile.When the slip parameter has high values, the thickness of the boundary layer is decreased and velocity varies and increases.The temperature within the border layer fluctuates for large viscoelastic parameters.By having a higher Peclet number, the microorganism field is reduced.The microorganism profile is weaker against incremented bioconvected Lewis number.The bioconvected nanofluid flow over lubricated disk is more ideal for improving heat transfer.Problems with thermodynamics and heat transfer benefit more from the current findings.
This particular challenge focuses on a specific scenario where a particular type of fluid, known as nanofluid, flows between two surfaces, namely a lubricated disk, while being influenced by biological processes called bioconvection.The potential applications of this challenge span a wide range of fields, encompassing biomedical engineering, microfluidics, tribology, nanotechnology, environmental engineering, pharmaceuticals, energy systems, aerospace engineering, and chemical engineering.It's important to note that this challenge is highly specialized and may not have immediate, real-world applications across all these domains.Nevertheless, the insights gained from investigating this problem have the potential to drive progress in these areas and inspire innovative solutions in future.Table 1.Numeric values of f 00 (0) for dissimilar K , n and l:

Figure 2 .
Figure 2. (a) Plot of l verses l on f 0 , (b) Plot of l verses u(z), (c) Plot of l verses f(z), and (d) Plot of l verses c(z).

Figure 6
describes the impact of Nb on the temperature.For greater values of Nb, an increment is recorded in the temperature and corresponding boundary layer thickness.For checking the behavior of Nb, and Le in contrast with concentration distribution f z ð Þ, Figures7 and 8are sketched.When l = 1, and we have noticed that concentration distribution usually decrease against Nb and Le, but increase for Le.We have observed that f z ð Þ decrease

Figure 3 .
Figure 3. (a) Plot of K verses f 0 , (b) Plot of K verses u(z), (c) Plot of K verses f(z), and (d) Plot of K verses c(z).

Figure 4 .
Figure 4. (a) Plot of n verses u(z), (b) Plot of n verses ;(z), and (c) Plot of n verses c(z).
displays the variance in organisms motility for different Peclet number values, and it can be seen that as Peclet number increases, the density curve gets flatter.Similar results can be shown in Figures 10 and 11 for increasing values of Lb and Mc.Tables 1 to 3 listed the various changes of the relevant parameters for skin friction, heat transfer rate, mass transfer rate, and microbe population.Here, we

Table 5 .
Case Stud Therm Eng 2021; 27: 101229.9. Madhu M, Kishan N and Chamkha AJ.Unsteady flow of a Maxwell nanofluid over a stretching surface in the presence of magnetohydrodynamic and thermal radiation effects.Propulsion Power Res 2017; 6: 31-40.10.Krishna MV, Swarnalathamma BV and Chamkha AJ.Investigations of Soret, Joule and Hall effects on MHD rotating mixed convective flow past an infinite vertical porous plate.J Ocean Eng Sci 2019; 4: 263-275.11.Chamkha AJ and Khaled ARA.Similarity solutions for hydromagnetic simultaneous heat and mass transfer by natural convection from an inclined plate with internal The solutions f 00 (0) at dissimilar slip parameter l values when K = 0.

Table 4 .
The velocity field comparisons for no-slip case (l !') when K = 0: