Concurrent Development of Thermal Energy with Magnetic Field on a Particle-Fluid Suspension Through a Porous Conduit
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The impact of heat transfer on the magnetohydrodynamic peristaltically induced motion in a channel through porous medium has been investigated. The continuity, momentum, and energy equations have been utilized to represent the flow in a closed form. These non-linear governing equations are solved analytically by employing the perturbation method. The obtained expressions for streamlines, temperature, and heat transfer coefficient are presented through graphs for two dimensions with a small wave number. The variations of physical variables with the pertinent parameters have been presented and discussed. It has been found that the inclusion of fluid suspension brought about a decrease in the temperature distribution. The effect of magnetic field on the temperature of fluid has also been seen to depend upon the position and time.
KeywordsHeat transfer Porous medium MHD Particle suspension Peristalsis
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Conflict of Interest
The authors declare that they have no conflict of interest.
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