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Exploration of Chemical Reaction Effects on Entropy Generation in Heat and Mass Transfer of Magneto-Jeffery Liquid

  • R. Mohapatra , B. Mahanthesh ORCID logo EMAIL logo , B.J. Gireesha and S.R. Mishra
Published/Copyright: September 18, 2018
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International Journal of Chemical Reactor Engineering
From the journal International Journal of Chemical Reactor Engineering Volume 16 Issue 9

Abstract

In many chemical engineering processes, a chemical reaction between a foreign mass and the fluid does occur. These processes find relevance in polymer production, oxidation of solid materials, ceramics or glassware manufacturing, tubular reactors, food processing, and synthesis of ceramic materials. Therefore, an exploration of homogeneous first-order chemical reaction effects on heat and mass transfer along with entropy analysis of Jeffrey liquid flow towards a stretched isothermal porous sheet is performed. Fluid is conducting electrically in the company of transverse magnetic field. Variations in heat and mass transfer mechanisms are accounted in the presence of viscous dissipation, heat source/sink and cross-diffusion aspects. The partial differential equations system governing the heat transfer of Jeffery liquid is reformed to the ordinary differential system through relevant transformations. Numerical solutions based on Runge-Kutta shooting method are obtained for the subsequent nonlinear problem. A parametric exploration is conducted to reveal the tendency of the solutions. The present study reveals that the Lorentz force due to magnetism can be used as a key parameter to control the flow fields. Entropy number is larger for higher values of Deborah and Brinkman numbers. It is also established that the concentration species field and its layer thickness of the Jeffery liquid decreases for a stronger chemical reaction aspect. To comprehend the legitimacy of numerical results a comparison with the existing results is made in this exploration and alleged an admirable agreement.

Keywords: chemical reaction; cross diffusion; entropy generation; heat source/sink; Jeffery fluid; MHD

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Received: 2017-12-03
Revised: 2018-04-19
Accepted: 2018-07-07
Published Online: 2018-09-18

© 2018 Walter de Gruyter GmbH, Berlin/Boston

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https://doi.org/10.1515/ijcre-2018-0005
Keywords for this article
chemical reaction; cross diffusion; entropy generation; heat source/sink; Jeffery fluid; MHD

Articles in the same Issue

  2. Experiment and Dynamic Simulation of PIG Motion during Pigging Operation in a Slope Pipeline
  3. Solar Radiation Effect on a Magneto Nanofluid Flow in a Porous Medium with Chemically Reactive Species
  4. Mathematical Modeling of Ethane Cracking Furnace of Olefin Plant with Coke Formation Approach
  5. Entropy Generation and Activation Energy Impact on Radiative Flow of Viscous Fluid in Presence of Binary Chemical Reaction
  6. Exploration of Chemical Reaction Effects on Entropy Generation in Heat and Mass Transfer of Magneto-Jeffery Liquid
  7. Response Surface Methodology Optimization for Photodegradation of Methylene Blue in a ZnO Coated Flat Plate Continuous Photoreactor
  8. Modeling of Fluid Bed Reactor of Ethylene Di Chloride Production in Abadan Petrochemical Based on Three-Phase Hydrodynamic Model
  9. Optimization and Reaction Kinetics Studies on Copper-Cobalt Catalyzed Liquid Phase Hydrogenation of 5-Hydroxymethylfurfural to 2,5-Dimethylfuran
  10. Role of Fe(III) and Oxalic Acid in the photo-Fenton System for 3-Methylphenol Degradation in Aqueous Solution under Natural and Artificial Light
  11. Assessment of the Efficiency of Aliquat 336+Rice Bran Oil for Separation of Acrylic Acid from Aqueous Solution Using Reactive Extraction
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