Trihybrid fluid flow with Arrhenius activation energy and slip conditions in porous space: A numerical analysis

Heat transport flow has a vital role in many disciplines such as environmental science, physics and engineering. Efficient heat transfer is essential for designing systems like heat exchangers, refrigeration systems and electronic devices. Attention here is concentrated for Darcy-Forchheimer flow of...

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Published inAlexandria engineering journal Vol. 117; pp. 534 - 544
Main Authors Shinwari, W., Hayat, T., Abbas, Z., Momani, S.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.04.2025
Elsevier
Subjects
(Al2O3,TiO2,SiO2) nanoparticles
Arrhenius activation energy
MHD flow
Slip conditions
Trihybrid nanofluid
(Al2O3,TiO2,SiO2) nanoparticles
Trihybrid nanofluid
MHD flow
Arrhenius activation energy
Slip conditions
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Abstract Heat transport flow has a vital role in many disciplines such as environmental science, physics and engineering. Efficient heat transfer is essential for designing systems like heat exchangers, refrigeration systems and electronic devices. Attention here is concentrated for Darcy-Forchheimer flow of ternary liquid. Curved stretchable sheet subject to slip conditions is taken.Top of Form Trihybrid nanofluid in this case is an aggregation of silicon dioxide, titanium dioxide, and aluminum oxide (Al2O3,TiO2andSiO2) as the nanoparticles and engine oil (conventional material). Organized material has impact of applied magnetic field, heat generation and activation energy. Incoming problems have been numerically computed employing finite difference method (FDM). Related systems invoking useful transformations are obtained. Thermal performance is better improved for trihybrid nanomaterials in comparison to other fluids including base fluid, hybrid fluid and nanofluid. To our information the slip conditions, activation energy and Joule heating in porous space for present flow consideration is not examined before. Comparison of estimated values here to previously published literature reveals an excellent agreement.
AbstractList Heat transport flow has a vital role in many disciplines such as environmental science, physics and engineering. Efficient heat transfer is essential for designing systems like heat exchangers, refrigeration systems and electronic devices. Attention here is concentrated for Darcy-Forchheimer flow of ternary liquid. Curved stretchable sheet subject to slip conditions is taken.Top of Form Trihybrid nanofluid in this case is an aggregation of silicon dioxide, titanium dioxide, and aluminum oxide (Al2O3,TiO2andSiO2) as the nanoparticles and engine oil (conventional material). Organized material has impact of applied magnetic field, heat generation and activation energy. Incoming problems have been numerically computed employing finite difference method (FDM). Related systems invoking useful transformations are obtained. Thermal performance is better improved for trihybrid nanomaterials in comparison to other fluids including base fluid, hybrid fluid and nanofluid. To our information the slip conditions, activation energy and Joule heating in porous space for present flow consideration is not examined before. Comparison of estimated values here to previously published literature reveals an excellent agreement.
Author Momani, S.
Hayat, T.
Shinwari, W.
Abbas, Z.
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Keywords (Al2O3,TiO2,SiO2) nanoparticles
Trihybrid nanofluid
MHD flow
Arrhenius activation energy
Slip conditions
Language English
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Snippet Heat transport flow has a vital role in many disciplines such as environmental science, physics and engineering. Efficient heat transfer is essential for...
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StartPage 534
SubjectTerms (Al2O3,TiO2,SiO2) nanoparticles
Arrhenius activation energy
MHD flow
Slip conditions
Trihybrid nanofluid
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Title Trihybrid fluid flow with Arrhenius activation energy and slip conditions in porous space: A numerical analysis
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