Performance enhancement of a DC-operated micropump with electroosmosis in a hybrid nanofluid: fractional Cattaneo heat flux problem |
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Authors: | Alsharif A M Abdellateef A I Elmaboud Y A Abdelsalam S I |
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Institution: | 1.Department of Mathematics and Statistics, College of Science, Taif University, P. O. Box 11099, Taif, 21944, Saudi Arabia ;2.Department of Applied Mathematics and Science, Faculty of Engineering, National University of Science and Technology, Seeb, 111, Sultanate of Oman ;3.Department of Mathematics, College of Science and Arts at Khulis, University of Jeddah, Jeddah, 21589, Saudi Arabia ;4.Department of Mathematics, Faculty of Science, Al-Azhar University (Assiut Branch), Assiut, 71254, Egypt ;5.Department of Basic Science, Faculty of Engineering, The British University in Egypt, Cairo, 11837, Egypt ; |
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Abstract: | The purpose of this investigation is to theoretically shed some light on the effect of the unsteady electroosmotic flow (EOF) of an incompressible fractional second-grade fluid with low-dense mixtures of two spherical nanoparticles, copper, and titanium. The flow of the hybrid nanofluid takes place through a vertical micro-channel. A fractional Cattaneo model with heat conduction is considered. For the DC-operated micropump, the Lorentz force is responsible for the pressure difference through the microchannel. The Debye-Hükel approximation is utilized to linearize the charge density. The semi-analytical solutions for the velocity and heat equations are obtained with the Laplace and finite Fourier sine transforms and their numerical inverses. In addition to the analytical procedures, a numerical algorithm based on the finite difference method is introduced for the given domain. A comparison between the two solutions is presented. The variations of the velocity heat transfer against the enhancements in the pertinent parameters are thoroughly investigated graphically. It is noticed that the fractional-order parameter provides a crucial memory effect on the fluid and temperature fields. The present work has theoretical implications for biofluid-based microfluidic transport systems. |
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Keywords: | hybrid nanofluid fractional Cattaneo heat flux Caputo-Fabrizio derivative |
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