Investigation of natural bio-convective flow of Cross nanofluid containing gyrotactic microorganisms subject to activation energy and magnetic field

Haq, Fazal; Saleem, Muzher; Rahman, Mujeeb Ur

doi:10.1088/1402-4896/abb966

Cited by 19 publications

(9 citation statements)

References 55 publications

(76 reference statements)

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“…Xia et al 8 addressed the natural convective optimized analysis for Eyring-Powell nanofluid subject to microorganisms. The cross nanofluid flow with entropy generation assessment was utilized by Haq et al 9 . In another reports, Haq et al 10 inspected the bioconvection applications for the nanofluid flow with controlled optimized phenomenon.…”

Section: Introductionmentioning

confidence: 99%

Darcy resistance flow of Sutterby nanofluid with microorganisms with applications of nano-biofuel cells

Aldabesh

Haredy

Al‐Khaled

et al. 2022

Sci Rep

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The objective of current research is to endorse the thermal aspect of Sutterby nanofluid containing the microorganisms due the stretched cylinder. The features of nonlinear thermal radiation, Darcy resistance and activation energy are also incorporated to inspect the thermal prospective. The problem is further extended with implementation of modified Fourier and Fick’s theories. The results are presented for the stretched cylinder and also for stationary plate. The numerical formulation for the problem is presented by following the shooting technique. The comparative numerical is performed to verify the computed simulations. The results convey that the presence of Darcy resistance parameter enhanced the velocity more effectively for stretched cylinder. A reduction in velocity due to Sutterby fluid parameter and buoyancy ratio parameter has been observed. Moreover, the temperature profile enhanced with larger sponginess parameter more effectively for stretching cylinder.

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Section: Introductionmentioning

confidence: 99%

Darcy resistance flow of Sutterby nanofluid with microorganisms with applications of nano-biofuel cells

Aldabesh

Haredy

Al‐Khaled

et al. 2022

Sci Rep

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“…They evaluated stratification and viscous dissipation phenomena. Recent investigations related to gyro-tactic organism characteristics in bio-convective nanofluid flow with stratification can be found in Alhussain et al (2021), Arafa et al (2021), Chu et al (2021), Haq et al (2020), Khan, Nadeem, et al (2020), Majeed et al (2020) and Rana et al (2020) and the references cited therein. All these techniques introduced for the analysis of gyro-tactic organism phenomena in bio-convective nanofluid flow models involve deterministic analytical and numerical solvers, while artificial intelligence (AI) methodologies based on stochastic numerical solvers look promising for the investigation of such systems.…”

Section: Introductionmentioning

confidence: 99%

Intelligent Bayesian regularization networks for bio-convective nanofluid flow model involving gyro-tactic organisms with viscous dissipation, stratification and heat immersion

Awan

Raja

Awais

et al. 2021

Engineering Applications of Computational Fluid Mechanics

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In the current study, a novel intelligent numerical computing paradigm based upon the foundation of the artificial neural networks legacy involving the Bayesian regularization (ANN-BR) approach has been implemented for the investigation of the non-uniform heat preoccupation process with the bio-convective flow dynamics of nanomaterial involving gyro-tactic microorganisms. The designed bio-convective stratified nanofluid flow (BCSNF) model initially represented by a system of PDEs is transformed into nonlinear ODEs by exploring appropriate transformations. The reference dataset for the BCSNF model was generated by the Adams numerical method for six scenarios by variation of the magnetic number, Brownian motion parameter, Prandtl number, bio-convection Lewis number, thermophoretic parameter, and bio-convection Peclet number. The approximate solutions were determined with 5-7 decimal places of accuracy and interpreted for the BCSNF model by the testing, training, and validation processes of the designed ANN-BR scheme. To check the efficiency of the introduced ANN-BR method, absolute error analysis, histogram studies, regression indices, and mean squared error (MSE) based figures of merit were used exhaustively to solve the variants of the BCSNF model involving gyro-tactic microorganisms with viscous dissipation, stratification, and heat immersion to study the influence of prominent parameters on the velocity, temperature, concentration, and motile density profiles.

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“…Kuznetsov 25 subsequently introduced this idea based on nanofluids, namely gyrotactic motile microorganisms, suggesting that the resultant large-scale flow of fluid produced by self-propelled motile gyrotactic microorganisms increases the mixture and prevents nanomaterials aggregation in nanofluids. Haq et al 26 studied the flow properties of Cross Nanoparticles across expanded surfaces subject to Arrhenius activation energy and magnetization field. Ahmad et al 27 examined a bioconvection nanofluid flow comprising gyrotactic motile microorganisms with a chemical reaction allowance through a porous medium past a stretched surface.…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation for bioconvectional flow of burger nanofluid with effects of activation energy and exponential heat source/sink over an inclined wall under the swimming microorganisms

Waqas

Farooq

Ibrahim

et al. 2021

Sci Rep

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Nanofluids has broad applications such as emulsions, nuclear fuel slurries, molten plastics, extrusion of polymeric fluids, food stuffs, personal care products, shampoos, pharmaceutical industries, soaps, condensed milk, molten plastics. A nanofluid is a combination of a normal liquid component and tiny-solid particles, in which the nanomaterials are immersed in the liquid. The dispersion of solid particles into yet another host fluid will extremely increase the heat capacity of the nanoliquid, and an increase of heat efficiency can play a significant role in boosting the rate of heat transfer of the host liquid. The current article discloses the impact of Arrhenius activation energy in the bioconvective flow of Burger nanofluid by an inclined wall. The heat transfer mechanism of Burger nanofluid is analyzed through the nonlinear thermal radiation effect. The Brownian dispersion and thermophoresis diffusions effects are also scrutinized. A system of partial differential equations are converted into ordinary differential equation ODEs by using similarity transformation. The multi order ordinary differential equations are reduced to first order differential equations by applying well known shooting algorithm then numerical results of ordinary equations are computed with the help of bvp4c built-in function Matlab. Trends with significant parameters via the flow of fluid, thermal, and solutal fields of species and the area of microorganisms are controlled. The numerical results for the current analysis are seen in the tables. The temperature distribution increases by rising the temperature ratio parameter while diminishes for a higher magnitude of Prandtl number. Furthermore temperature-dependent heat source parameter increases the temperature of fluid. Concentration of nanoparticles is an decreasing function of Lewis number. The microorganisms profile decay by an augmentation in the approximation of both parameter Peclet number and bioconvection Lewis number.

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Investigation of natural bio-convective flow of Cross nanofluid containing gyrotactic microorganisms subject to activation energy and magnetic field

Cited by 19 publications

References 55 publications

Darcy resistance flow of Sutterby nanofluid with microorganisms with applications of nano-biofuel cells

Darcy resistance flow of Sutterby nanofluid with microorganisms with applications of nano-biofuel cells

Intelligent Bayesian regularization networks for bio-convective nanofluid flow model involving gyro-tactic organisms with viscous dissipation, stratification and heat immersion

Numerical simulation for bioconvectional flow of burger nanofluid with effects of activation energy and exponential heat source/sink over an inclined wall under the swimming microorganisms

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