EMHD creeping rheology of nanofluid through a micro-channel via ciliated propulsion under porosity and thermal effects

Javid, Khurram; Ellahi, Mazhar; Al‐Khaled, Kamel; Raza, Mohsin; Khan, Sami Ullah; Khan, M. Ijaz; El‐Zahar, Essam R.; Gouadria, Soumaya; Afzaal, Muhammad F.; Khan, Md. Mobarak Hossain

doi:10.1016/j.csite.2021.101746

Cited by 34 publications

(2 citation statements)

References 33 publications

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“…Some interesting studies of fabricated cilia in the perception of microfluidic processing, instantaneous mixing and pumping are mentioned [16][17][18][19]. In this regime, Javid et al [20] presented a mathematical model of pumping transport induced by cilia stimulated asymmetric metachronal waves and reported that prolonged cilia contribute to fluid flow enhancement. Abo-Elkhair [21] discussed the effect of a ciliated wall on the pumping motion of magneto viscous fluid.…”

Section: Introductionmentioning

confidence: 99%

Thermal Case Study of Cilia Actuated Transport of Radiated Blood-Based Ternary Nanofluid under the Action of Tilted Magnetic Field

et al. 2022

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Micro/nanoscale fabricated devices have widely been used in modern technology and bioengineering as they offer excellent heat transfer. Removal of excess heat, coolant selection, rapid mixing, and handling proportion of colloidal metallic nanogranules in the base fluid are the main challenges in micro/nanofluidic systems. To address these problems, the primary motivation of the intended mathematical flow problem is to investigate the thermal and flow aspects of blood-based ternary nanofluid in the presence of inclined magnetic field and thermal radiations through a microfluidic pump with elastic walls. Further, the pump inner surface is smeared with fabricated cilia. The embedded cilia blow in coordination to start metachronal travelling waves along the pump wall that assist homogenous mixing and manipulation. The entire analysis is conducted in moving frame and simplified under lubrication and Rosseland approximations. Numerical solution of various flow and thermal entities are computed via the shooting method and plotted for different values of the parameters of interest. A comparative glimpse allows us to conclude that the trimetallic blood-based nanofluid exhibits elevated heat transfer rate by 12–18%, bi-metallic by about 11–12%, and mono nanofluid by about 6% compared to the conventional blood model. The study also determines that the prolonged cilia commence augmentation in flowrate and pressure-gradient around the pump deep portion. Furthermore, the radiated ternary liquid under fragile magnetic field effects may contribute to the cooling process by eliminating unnecessary heat from the system. It is also noticed that around the ciliated wall, the heat transfer irreversibility effects are appreciable over the fluid frictional irreversibility.

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Section: Introductionmentioning

confidence: 99%

Thermal Case Study of Cilia Actuated Transport of Radiated Blood-Based Ternary Nanofluid under the Action of Tilted Magnetic Field

et al. 2022

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“…Zeb et al [31] deliberated the Eyring-Powel ferrofluid with the addition of thermal radiative effect and magnetic dipole along with chemical reaction subjected to heterogeneous and homogeneous situations over a stretchable surface computed via the Runge-Kutta method with shooting procedure. Javid et al [32] examined the physical impacts of electro-osmosis and magnetic fields embedded in porosity and thermal slip-on flow on nanofluid via an asymmetric microchannel accomplished with convective boundary conditions. Aldabesh et al [33] researched the features of Darcy resistance and Arrhenius activation energy on the aspect of a nanofluid occupied with microorganisms via an extended cylinder.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Methodology for the Computational Behaviour of Thermal Radiation and Chemical Reaction on Viscoelastic Nanofluid Flow

Pattnaik

Mishra

Panda

et al. 2022

Mathematical Problems in Engineering

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The current investigation carries out the free convection of an electrically conducting viscoelastic nanofluid through an expanding surface. The salient features of Brownian and thermophoresis due to cross-diffusion and thermal radiation enhance the heat transport phenomenon. Furthermore, the chemical reaction plays an important role in enriching the study. The current investigation shows its important role, such as the proper shape and size of the product in the final stage of production and also optimizing the transport phenomena of various industries that depend upon the supplied heat source, etc. With the appropriate selection of transformation rules, the proposed model is designed and transformed into the ordinary. Furthermore, a hybrid methodology such as the “Perturbation Method” and numerical technique, i.e., the “MATLAB solver (bvp4c technique),” is proposed to handle the governing equations. The graph and tabular form illustrate the characteristics of physical parameters blending within the flow phenomena.

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3-D simulations for maximum values of fluid distributions over separated contours on MHD peristaltic flow of pseudoplastic nanofluid in variable electric conductivity: solar applications

Sfina,

Ibrahim

2024

Arch Appl Mech

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EMHD creeping rheology of nanofluid through a micro-channel via ciliated propulsion under porosity and thermal effects

Cited by 34 publications

References 33 publications

Thermal Case Study of Cilia Actuated Transport of Radiated Blood-Based Ternary Nanofluid under the Action of Tilted Magnetic Field

Thermal Case Study of Cilia Actuated Transport of Radiated Blood-Based Ternary Nanofluid under the Action of Tilted Magnetic Field

Hybrid Methodology for the Computational Behaviour of Thermal Radiation and Chemical Reaction on Viscoelastic Nanofluid Flow

3-D simulations for maximum values of fluid distributions over separated contours on MHD peristaltic flow of pseudoplastic nanofluid in variable electric conductivity: solar applications

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