Dynamics of magneto-electric hybrid nanoparticles with chemically reacting and radiated moving plate: Entropy analysis

In this new era of fluid field, researchers are interested in hybrid nanofluid because of its thermal properties and potential, which are better than those of nanofluid when it comes to increasing the rate at which heat is transferred. In comparison to the dynamics of chemically reactive Ethylene Gl...

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Published inInternational communications in heat and mass transfer Vol. 138; p. 106325
Main Author Raju, S. Suresh Kumar
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.11.2022
Subjects
bvp4c
Chemical reaction
Entropy generation
Hybrid nanofluid
Moving surface
Thermal radiation
Moving surface
Thermal radiation
Chemical reaction
Entropy generation
bvp4c
Hybrid nanofluid
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Abstract In this new era of fluid field, researchers are interested in hybrid nanofluid because of its thermal properties and potential, which are better than those of nanofluid when it comes to increasing the rate at which heat is transferred. In comparison to the dynamics of chemically reactive Ethylene Glycol - Zinc Oxide (nanofluid) and Ethylene Glycol - Zinc Oxide - Titanium dioxide (hybrid nanofluid) over a moving surface, nothing is known in terms of thermal radiation, entropy formation, viscous dissipation, and the Lorentz force. The thermo-physical characteristics of Ethylene Glycol, Zinc Oxide nanoparticles, and Titanium dioxide nanoparticles are used in this study to derive the governing equations for the transport of both dynamics. Flow-driven equations are transformed into nonlinear ODEs and solved using MATLAB bvp4c solver. It is noticed that, when magnetic field parameter (M) takes input in the range 0 ≤ M ≤ 3, skin friction coefficient decreases at a rate of 0.22052 (in case of hybrid nanofluid) and 0.19203 (in case of nanofluid) per unit value of magnetic field parameter. It is detected that the rise in Brinkmann number causes a rise in entropy generation and Bejan number decreases as Brinkmann number increases. Furthermore, when Eckert number rises, the heat transmission rate decreases. The heat transmission rate drops at a rate of 0.0869 (in case of hybrid Nanofluid) and 0.07429 (in case of nanofluid) when Eckert number (Eck) takes input in the range 0 ≤ Eck ≤ 0.7. The mass transmission rate increases at a rate of 1.013383 (in case of hybrid nanofluid) and 1.013125 (in case of nanofluid) when Schmidt number (Sc) takes input in the range 0 ≤ Sc ≤ 1. A comparison of the current results to previous results indicated a satisfactory agreement under certain conditions. •Irreversibility analysis of hybrid nanofluid flow over a moving plate with chemical reaction and thermal radiation is considered.•Viscous dissipation and Joule heating are also included in the energy equation. Whereas skin friction coefficient decreases as the volume fraction of the nanoparticle increases.•The rise in the value of the chemical reaction parameter correlates to an increase in the mass transfer rate.•An increase in the Brinkmann number results in an increase in entropy generation, but the Bejan number falls as the Brinkmann number rises.
AbstractList In this new era of fluid field, researchers are interested in hybrid nanofluid because of its thermal properties and potential, which are better than those of nanofluid when it comes to increasing the rate at which heat is transferred. In comparison to the dynamics of chemically reactive Ethylene Glycol - Zinc Oxide (nanofluid) and Ethylene Glycol - Zinc Oxide - Titanium dioxide (hybrid nanofluid) over a moving surface, nothing is known in terms of thermal radiation, entropy formation, viscous dissipation, and the Lorentz force. The thermo-physical characteristics of Ethylene Glycol, Zinc Oxide nanoparticles, and Titanium dioxide nanoparticles are used in this study to derive the governing equations for the transport of both dynamics. Flow-driven equations are transformed into nonlinear ODEs and solved using MATLAB bvp4c solver. It is noticed that, when magnetic field parameter (M) takes input in the range 0 ≤ M ≤ 3, skin friction coefficient decreases at a rate of 0.22052 (in case of hybrid nanofluid) and 0.19203 (in case of nanofluid) per unit value of magnetic field parameter. It is detected that the rise in Brinkmann number causes a rise in entropy generation and Bejan number decreases as Brinkmann number increases. Furthermore, when Eckert number rises, the heat transmission rate decreases. The heat transmission rate drops at a rate of 0.0869 (in case of hybrid Nanofluid) and 0.07429 (in case of nanofluid) when Eckert number (Eck) takes input in the range 0 ≤ Eck ≤ 0.7. The mass transmission rate increases at a rate of 1.013383 (in case of hybrid nanofluid) and 1.013125 (in case of nanofluid) when Schmidt number (Sc) takes input in the range 0 ≤ Sc ≤ 1. A comparison of the current results to previous results indicated a satisfactory agreement under certain conditions. •Irreversibility analysis of hybrid nanofluid flow over a moving plate with chemical reaction and thermal radiation is considered.•Viscous dissipation and Joule heating are also included in the energy equation. Whereas skin friction coefficient decreases as the volume fraction of the nanoparticle increases.•The rise in the value of the chemical reaction parameter correlates to an increase in the mass transfer rate.•An increase in the Brinkmann number results in an increase in entropy generation, but the Bejan number falls as the Brinkmann number rises.
ArticleNumber 106325
Author Raju, S. Suresh Kumar
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Chemical reaction
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bvp4c
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Snippet In this new era of fluid field, researchers are interested in hybrid nanofluid because of its thermal properties and potential, which are better than those of...
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SubjectTerms bvp4c
Chemical reaction
Entropy generation
Hybrid nanofluid
Moving surface
Thermal radiation
Title Dynamics of magneto-electric hybrid nanoparticles with chemically reacting and radiated moving plate: Entropy analysis
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