RETRACTED: Energy and mass transport through hybrid nanofluid flow passing over an extended cylinder with the magnetic dipole using a computational approach

Abstract

The objective of this research is to evaluate the heat and mass transfer in a water-based Darcy–Forchheimer hybrid nanofluid (HNF) flow across an expanding cylinder. The fluid flow has been studied under the influence of a magnetic field, viscous dissipation, heat source, thermal radiation, concentration stratification, and chemical reaction. Carbon nanotubes (CNTs) and iron ferrite (Fe₃O₄) nanoparticles (NPs) are added to the water, for the purpose of synthesizing the HNF. The fluid flow has been induced in the presence of gyrotactic microorganisms and the non-Fick’s model. Microorganisms are used to stabilize scattered nanoparticles through the hybrid nanofluid. The phenomena have been modeled in the form of a nonlinear system of partial differential equations (PDEs). The modeled equations are reduced to a dimensionless system of ODEs by using similarity substitution. The numerical solution of the derived sets of nonlinear differential equations is obtained by using the parametric continuation method. The impact of physical constraints on temperature, velocity, concentration, and microorganism profiles is presented through figures and tables. It has been observed that the heat and mass transport rates increase with the rising effect of the curvature parameter, while declining with the effect of the thermal stratification parameter.

Introduction

The study of boundary layer flow through a cylinder gained the attention of researchers due to its broad array of applications in numerous sectors, including manufacture and extraction of glass fiber, bridges and funnel stacks in civil engineering, paper production, melt-spinning rubber sheets, blood transportation in heart-lung machine, risers and channels, polymer production, carriage of noxious fluids at nuclear power plants, carriage of destructive fluids when fluid contact with machinery and equipment is restricted, and many others (Ma et al., 2020; Dou, 2022; Hussain et al., 2022). For about the last 2 decades, various investigators chose to conduct their research in the cylindrical channel because of the aforementioned applicability. The mathematical analysis of power-law nanofluid flow across a circular surface is documented by Ullah et al. (2021a) who concluded that the natural frequency has a momentous effect on the fluid’s properties. Zhang et al. (2021) numerically assessed the HNF flow across a circular cylinder. It was observed that the rotating cylinders containing a splitting sheet, may be effective options for energy transfer. Numerical simulations and tests to lower the drag of a cylinder for both smooth and round cylinders with dimpled surfaces are investigated by Ullah et al. (2021b). The results show that within a particular range of Reynolds numbers, the dimpled structure can efficiently reduce cylinder drag, with a maximum drag reduction rate of up to 19%. Using the modified Fourier heat flux law, Varun Kumar et al. (2021) scrutinized the upshot of hybrid NPs on the dusty flow behavior through an enlarging cylinder. Their observations show that increasing particle mass concentration reduces the velocity and temperature gradient, whereas increasing the curvature factor increases the thermal gradient and velocity within the boundary. Poply (2021) evaluated the influence of MHD flux over an extending cylinder with a heat source. Their research aided in controlling the frequency of energy transmission and flow stream in a variety of industrial applications and manufacturing processes to achieve the desired end production efficiency. The influence of MHD Newtonian nanofluid flow across a stretchable cylinder was inspected by Waqas et al. (2021). The fallouts reveal that the velocity is increased by increasing the buoyancy constraint and declines by increasing the magnetic parameter. Chu et al. (2022b) analyzed the Maxwell MHD NF flow over a prolonged cylinder using nonlinear heat emission. An incompressible and 2D flow of viscoelastic NF over an extended cylinder was considered by Al-Mubaddel et al. (2022). Dey et al. (2021) investigated boundary layer viscous fluid flow via a stretchable cylinder with varying heat flux and molecular diffusion. They observed that due to the stretching of the cylinder, dual solutions are discovered, and an unusual increase in heat near the cylinder’s surface. Energy consumption has grown exponentially over the world, demanding more efficient energy use because the demand exceeds the supply. Within a thermal system, a significant quantity of temperature is generated, needing efficient and rapid heat transfer employing high-performance thermal management systems. Some new efforts have been documented by many academics on fluid flow across different configurations (Chu et al., 2021; Zhao et al., 2021; Benhacine et al., 2022; Kumar and Sahu, 2022; Lim et al., 2022).

Many modern technological applications that previously required ordinary fluids (water, engine oil, ethylene glycol, and propylene glycol) have been replaced with nanofluids, which are the composition of the base fluid with nano-sized particles (Alsallami et al., 2022; Bhatti et al., 2022a; Rafiei et al., 2022). Nanofluids have garnered a huge interest in research and development in the last decade, especially in the fields of heat assignment improvement techniques and renewable and sustainable energy systems. Solar collectors, hydrodynamics, hydropower rotors, thermodynamics, ocean power plants, wind turbines, and geothermal heat exchangers are just a few of the applications for nanofluids (Ma et al., 2021). A new mechanism of thermal expansion within nanofluids has recently been introduced. The process involves mixing two or more different nanoparticles in the primary fluid. These nanofluids are referred to as hybrid nanofluids, and they have a higher heat transfer efficiency due to their improved thermo-physical properties. Propagation of the HNF flow and heat and mass transport play essential roles in biotechnology, crude oils, nuclear sectors, paper manufacturing, suspended and colloidal solutions, polyethylene solution, geophysics, unusual lubricants, and chemical plants, which are only some of the uses in the industry (Kumar et al., 2022). The fluid flow of a blood-based HNF with variable viscosity and CNTs via a stretching sheet was discovered by Chu et al. (2022a). The inclusion of CNTs proved to be more successful, according to their findings. Shruthy and Mahanthesh (2019) discussed the thermal Bénard convection analytically in HNF and Casson fluid. It has been discovered in their finding that using a hybrid nanofluid to postpone convection can improve the rate of heat allocation. A two-dimensional time-dependent radiative Casson fluid flow across a porous stretched superficial is examined by Zhou et al. (2021). They discovered that as the Casson component and magnetic field rise, the friction drags increase, whereas the Nusselt number drops with increasing Eckert number. Syam Sundar et al. (2015) measured the heat exchange ratio and friction coefficient for CNT- Fe₃O₄/water HNF flow through a cylinder under constant heat flux. Soran et al. Lung et al. (2021) evaluated the efficacy of carboxylic-synthesized CNTs modified with Fe and Mn metal to remove two pesticides from an aqueous medium. Their findings demonstrate that the CNT-COOH/MnO₂/Fe₃O₄ NPs are a viable adsorbent for the removal of pesticides from wastewater. The NPs’ shape characterization and the heat transfer characteristics of an Au–Fe₃O₄–blood HNF flowing across a stretching surface over a magnetohydrodynamic medium were presented by Ullah et al. (2019). The thermal conductivity of blade-shaped Au and Fe₃O₄ nanoparticles is found to be superior to platelet, needle, cylinder, brick, and sphere shapes. To create blood-based HNF, Mohamed et al. (2021) quantitatively studied CoFe₂O₄ and Fe₃O₄ ferroparticles embedded in Casson fluid, which resembles human blood. According to their findings, when magnetic effects were present, the CNT-based Casson NF flow offered 46% more heat than blood-based NF. Many scholars have recently studied hybrid nanofluid flow comprised of CNTs and iron oxide nanoparticles (Alharbi et al., 2022; Bhatti et al., 2022b; Elattar et al., 2022; Khashi’ie et al., 2022; Nazeer et al., 2022; Ullah et al., 2022).

Bioconvection has a huge involvement in manufacturing and medicine (Areekara et al., 2021; Khan et al., 2021). Elayarani et al. (2021) described the adaptive neuro-fuzzy inferential simulations for the unsteady 2D bio-convective flow of Carreau NF containing gyrotactic microbes over an elongating sheet with magnetism and multiple slip conditions. Hosseinzadeh et al. (2020) explored cross-fluid flow on a horizontal and 3D cylinder with gyrotactic microbes and NPs while accounting for viscous dissipation and magnetic field. Muhammad et al. (2021) evaluated the flow of magnetized viscoelastic Carreau NF carrying microbes through a sliding wedge with slip effects and thermal radiation parameters. Waqas et al. Muhammad et al. (2022) considered the features of the Jeffrey nanofluid flow over a sheet and the effects of activation energy and motile microorganisms. It was observed that the bioconvection Rayleigh number and resistance ratio parameter play an essential role in the Jeffery nanofluid’s falling flow. Ahmad et al. (2022) investigated the novel properties of hybrid nanofluids such as NiZnFe₂O₄ and MnZnFe₂O₄. Recently, gyrotactic microorganism fluid flow and the comprising nanoparticles have been reported by Alhowaity et al. (2022b), Ashraf et al. (2022), and Habib et al. (2022).

The current research focuses on the amazing evaluation of CNTs and iron oxide-based HNF flow with magnetic dipole and triple stratification over an extending cylinder. Viscous dissipation, heat radiation, generalized Fick’s law, and partial slide are also taken into account. The proposed study is significant because it examines the chemically reactive CNTs + Fe₃O₄/water Casson hybrid nanofluid with magnetic dipole and stratification effects created by an elongating cylinder. To the best of our experience, no previous research has looked into these impacts. The MATLAB function PCM and bvp4c have been used to estimate the numerical simulation of the current analysis. Graphs depict the effects of various parameters, while tables show the statistical valuation of skin friction, Nusselt number, and microorganisms .

FIGURE 1

Mathematical formulation

Over an extending cylinder, we addressed a 2D laminar and radiative Casson HNF flow in the presence of slip and microbe effects. The CNTs and iron oxide are described as NPs in the Casson fluid. The magnetic effect is executed in the r-direction. The temperature, concentration, and microorganism are symbolized as , , and , respectively. Under the aforementioned description, the leading equations are expressed as (Ahmad et al., 2021)Here, determine the velocity factors in the x and r direction, respectively, while is the dynamic viscosity, is the thermal diffusivity, is the mass diffusivity, is the density, is the microorganism diffusivity, is the concentration relaxation time, and is the slip factor. Additionally, denotes the ferromagnetic force.

The boundary conditions are expressed as (Ahmad et al., 2021)In the aforementioned equation, specifies the magnetic strength. shows the kinematic viscosity of the hybrid nanofluid, while , and are the constant number.

The magnetic dipole is specified asThe absolute magnetic field iswhere,andThe magnetic field became more intense, and a linear link between magnetic and temperature variation was formed as follows :

Similarity transformation

The similarity variables are (Ahmad et al., 2021)By applying the aforementioned similarity transformation, Eq. 1 is identically satisfied while Eqs 2–5 take the form asThe reduced boundary conditions areHere, is the microorganism stratification, is the curvature term, the bio‐convection constant, is the Casson fluid constraints, is the thermal stratification, M is the ferromagnetic term, is the concentration stratification, Ec is the Eckert number, is the velocity slip, is the radiation constant, is the Peclet number, is the free stream parameter, is the Lewis number, is the Prandtl number, is the Schmidt number, is the concentration relaxation constraints, is the chemical reaction term, and is the viscous dissipation parameter.

These physical terms are expressed as (Ahmad et al., 2021)The physical interest quantities derived from the present study areThe non-dimensional forms of the physical quantities are

Numerical solution

After discretization, the obtained set of equations is computed through Matlab code of PCM.

Results and discussion

For hybrid NF consisting of CNTS and magnetic ferrite NPs, the discussion section examines the comportment of velocity, energy, and motile microbe profile against the change of numerous physical restrictions. The comparative Figures 2–5 and Tables 2–4 exhibit their outcomes.

FIGURE 2

FIGURE 3

FIGURE 4

FIGURE 5

Figure 1 illustrates the physical mechanism of fluid flow over a stretching cylinder. Figures 2A–E exemplify the variations in the velocity profile for the curvature parameter , ferromagnetic parameter , fluid parameter , volume fraction , and slip parameter , respectively. The results indicate that the velocity field shows a reducing trend for the enhanced values of the curvature constraint. It is observed in the result that as the curvature factor is increased, the radius of the cylinder shrinks which produces minimal resistance to fluid flow, and therefore, the fluid velocity increases. The decreasing behavior of the velocity profile for the variation of ferromagnetic parameter can be seen in Figure 2B. The reason for this decline is that when the ferromagnetic parameter increases, a stronger resistive force arises known as Lorentz force which decreases the fluid velocity. The velocity profile displays a declining behavior for the rising values of the Casson fluid factor, as shown in Figure 2C. The reason behind this decline is that as the Casson parameter increases, the fluid acts like a Newtonian fluid which reduces the velocity field. Figure 2D shows the upshot of on . Higher valuation of diminishes the velocity field. By expanding the volume percentage, the transit, adhesive force, and excitation energy across CNTs and Fe₃O₄ NF reduce, resulting in a drop in the velocity field. Figure 2E shows the upshot of the velocity slip constraint S on the fluid velocity. The graph indicates the decrease in the fluid velocity due to growing values of S. It is due to velocity difference between near the surface and away from the cylinder.

The influence of , , , , , and on the energy profile is shown in Figures 3A–F. The impact of the curvature on the energy outlines is seen in Figure 3A. The heat transfer improves as the values of improve, as seen in the figures. Physically, as the curvature term upsurges, the radius of the cylinder expands, due to which the maximum number of NPs are attached to the surface of the cylinder, which transmits more heat, so the temperature field improves. Figure 3B shows influence of (Casson fluid) on the energy contour . The temperature distribution improves with improved values, as shown in the figure. It is shown that the Casson term is in an inverse relation to the yield stress. The influence of the magnetic coefficient and on the energy dispersal is seen in Figures 3C,D. Improvement in the fluid temperature corresponded to rises in the magnetic effect and solid volume fraction parameter , as seen in the figures. A resistive pressure is created when the magnetic field is improved, which raises the temperature of the fluid. In Figure 3E, the effect of the radiation term Rd on the fluid’s temperature field is investigated. As the radiation number upsurges, the fluid temperature rises. When the radiation term is increased, the fluid absorbs more heat, causing the fluid temperature to rise. The impact of thermal stratification parameter is shown in Figure 3F. It is to be noted that the energy profile decreases for larger values of .

The effects , , , , and on concentration profile are shown in Figures 4A–E. Figure 4A shows the influence of the volume fraction indicator for both CNTs and iron ferrite NF on the mass profile. Because the fluid average viscosity becomes dense as the quantity of iron oxide NPs and CNTs increases, the mass transfer rate slows. As a result, as credit grows, the concentration profile decreases. Figure 4B shows that the curvature parameter is a decreasing function of mass transfer . The mass transmission rate reduces with increases in . Figure 4C indicates the influence of the concentration profile. By increasing the values of S_c, the concentration profile decreases. Because increasing the value of Sc lowers the mass permeability, the mass rate falls. Figure 4D depicts the variance in the concentration profile sketch as a function of various estimations of the concentration relaxation. It is stated that a higher mass relaxation factor approximation lowers the concentration profile. The effect of the concentration stratification coefficient on the concentration distribution is shown by Figure 4E. The augmentation of the concentration stratification factor results in a diminution in the sketch and the related boundary layer thickness.

Figures 5A,B show the consequences of and on the microbial density sketch. The microorganism frequency and corresponding boundary layer thickness show an increasing tendency for larger values of and , as shown in Figures 5A,B. Figures 5C–E show that the effect of , , and on declines the motile microorganism profile. Physically, is in an inverse relation with the mass diffusion and an increase in results in the reduction of . Additionally, it is observed that rising values of destabilize the gyrotactic microbes’ profile and a higher enhances the progress of NF flow.

Tables 1, 2 revealed the experimental values of base fluid and nanoparticles and the mathematical model used for the proposed model. Table 3 shows the statistical assessments of skin friction , mass transfer , heat transfer rate , and motile microorganism transmission rate . Table 4 shows the comparative analysis between SWCNTs and MWCNTs for the microorganism transfer rate.

Conclusion

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