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Influence of chemical reaction on electro-osmotic flow of nanofluid through convergent multi-sinusoidal passages

Noureddine Elboughdiri, Khurram Javid, Muhammad Shehzad, Yacine Benguerba

2024Case Studies in Thermal Engineering11 citationsDOIOpen Access PDF

Abstract

In the present study, the influences of chemical reactions on heat transfer and the peristaltic pumping of nanofluid in a convergent channel are analyzed. This mathematical analysis is looked at under the postulates of greater wavelength and smaller Reynold's number. The governing equations are initially transformed from fixed to a wave frame by using linear transformations. Furthermore, these transformed equations are non-dimensioned with the help of similarity variables. Due to the complex form of non-dimensional flow equations, numerical solutions for velocity profile, stream function, temperature profile, and nanoparticle concentration are obtained with the help of Mathematica 11.0 software. These numerical solutions are described via graphs in Mathematica software. These numerical solutions are plotted for numerous rheological parameters. The transportation of nanofluid is based upon multi-sinusoidal natures (cosine wave, sine wave, triangular wave, square wave, sawtooth wave) of peristaltic waves. It is found that with an increasing heat source parameter, the channel flow is decelerated due to the magnitudes of velocity profile and stream function are reduced. While sharp enhancements are noticed in both temperature and nanoparticle concentration by increasing the heat source parameter under chemical reaction effects. The high temperature is obtained with larger chemical reactions. The contrast among viscous and non-viscous fluids is also addressed. A significant enhancement is observed in both velocity profile and stream function by increasing the electroosmotic parameter. The study is relevant to nano-cooling systems, drug delivery systems, and microfluidic pumps where laminar flows in convergent domains arise. This model is significant for the thermal enhancement of mechanical and chemical rheological processes.

Topics & Concepts

NanofluidLaminar flowStream functionMechanicsSine waveSawtooth waveMaterials scienceStreamlines, streaklines, and pathlinesReynolds numberFlow (mathematics)WavelengthPhysicsHeat transferThermodynamicsOpticsComputer scienceTurbulenceComputer visionVoltageVortexQuantum mechanicsVorticityNanofluid Flow and Heat TransferHeat Transfer MechanismsFluid Dynamics and Turbulent Flows