Thermal and Mass Transport Enhancements in Casson Ternary Hybrid Nanofluid Flow through an Exponentially Stretching Cylinder: Accounting for Darcy-Forchheimer and Arrhenius Effects

Nath, Jintu Mani; Chamkha, Ali J; Paul, Ashish; Das, Tusar Kanti

doi:10.24200/sci.2024.63995.8699

Thermal and Mass Transport Enhancements in Casson Ternary Hybrid Nanofluid Flow through an Exponentially Stretching Cylinder: Accounting for Darcy-Forchheimer and Arrhenius Effects

Articles in Press

Document Type : Research Note

Authors

¹ Department of Mathematics, Mangaldai College, 784125, Assam, India

² Faculty of Engineering, Kuwait College of Science and Technology, Doha District, 35004 Kuwait

³ Department of Mathematics, Cotton University, Guwahati-781001, India

⁴ Department of Mathematics, Dudhnoi College, Dudhnoi-783124, Assam, India

10.24200/sci.2024.63995.8699

Abstract

The primary goal of this study is to investigate the shear-thinning ternary hybrid magnetohydrodynamics nanofluid flow through an exponentially stretched cylinder incorporating Arrhenius energy and varying thermal conductivity. Darcy-forchheimer impact and a magnetic field are also employed in this flow model. The Casson ternary hybrid nanofluid mechanism is utilized in conjunction with Molybdenum disulfide, Silver, and Copper nanoparticles. The assortment of partial differential equations (PDEs) in the mathematical framework is simplified to ordinary differential equations (ODEs) by implementing the similarity transformation. MATLAB computing approach Bvp4c is used to achieve the numerical solutions for regulating ODEs and portray the graphs for numerous emerging variables. The core findings indicate that the non-Newtonian ternary hybrid nanofluid highlights a more noticeable thermal and mass transport enrichment than the hybrid nanofluid. The thermal transmission rate for polymer-based trihybrid nanofluid is almost 3% superior in contrast to hybrid nanofluid. Also, the absolute shear rate for ternary hybrid nanofluid is nearly 5.02% better than the hybrid nanofluid. Additionally, the research significantly advances the forecasting of the significance of shear-thinning ternary hybrid nanofluid in the thermal transport processes. The findings reflect strong consistency with earlier released studies.

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Thermal and Mass Transport Enhancements in Casson Ternary Hybrid Nanofluid Flow through an Exponentially Stretching Cylinder: Accounting for Darcy-Forchheimer and Arrhenius Effects

Articles in Press, Accepted Manuscript
Available Online from 17 September 2024

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Thermal and Mass Transport Enhancements in Casson Ternary Hybrid Nanofluid Flow through an Exponentially Stretching Cylinder: Accounting for Darcy-Forchheimer and Arrhenius Effects

Articles in Press, Accepted Manuscript Available Online from 17 September 2024

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Articles in Press, Accepted Manuscript
Available Online from 17 September 2024