Interaction of Variable Fluid Properties with Electrokinetically Modulated Peristaltic Flow of Reactive Nanofluid: A Thermodynamical Analysis

In the present study, the interaction of variable fluid properties with electrokinetically regulated peristaltic transportation of a reactive nanofluid embedded in a porous space is studied. The nanofluid saturates the porous space/medium with inhomogeneous porosity, which changes with distance from...

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Bibliographic Details
Published in:Mathematics (Basel) 2022-11, Vol.10 (23), p.4452
Main Authors: Akbar, Yasir, Huang, Shiping, Alotaibi, Hammad
Format: Article
Language:English
Subjects:
Analysis
Boundary conditions
Brownian motion
Chemical reactions
Electric fields
Electric properties
electrokinetic forces
Electrokinetics
Energy dissipation
Heat conductivity
Heat transfer
Magnetic fields
Mechanical properties
Nanofluids
Nanoparticles
Nonlinear equations
Ohmic dissipation
Optimization
Parameters
Particle flow
Porous materials
Porous media
Resistance heating
Schmidt number
Thermal conductivity
Thermal properties
Thermodynamic processes
Thermophoresis
variable fluid properties
variable porosity
Viscosity
zero mass flux
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Summary:In the present study, the interaction of variable fluid properties with electrokinetically regulated peristaltic transportation of a reactive nanofluid embedded in a porous space is studied. The nanofluid saturates the porous space/medium with inhomogeneous porosity, which changes with distance from the channel boundary. It is assumed that nanofluids are accompanied by variable thermal conductivity and viscosity. The impacts of magnetic field, Brownian motion, electric field, viscous dissipation, chemical reaction, mixed convection, and thermophoresis are incorporated. Moreover, the contribution of zero mass flux boundary condition is executed. The complexity of the equations describing the flow of a nanofluid is reduced by applying the lubrication theory. The fully non-linear equations are solved by utilizing a numerical technique. Particular attention is paid to the analysis of entropy optimization, since its minimization is the best measure to enhance the efficiency of thermal systems. These results demonstrate that a positively oriented external electric field contributes to an increase in nanofluid velocity. Temperature of nanofluid increases more rapidly due to an augmentation in Joule heating parameter. It is noticed that the temperature of water is comparatively lower than that of kerosene. The system’s energy loss can be reduced when the thermal conductivity parameter enhance. The magnitude of Bejan number is enhanced by increasing electroosmotic parameter. Further, a substantial decrement in concentration profile is perceived when the Schmidt number is augmented.
ISSN:2227-7390
2227-7390
DOI:10.3390/math10234452