Numerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method

Hybrid nanofluids have generally been used to improve the applications heat transfer as a heat exchanger due to its significant thermos-physical properties compared to conventional fluid. In this article, 3D axis symmetric flow and heat dissipation over a hybrid nano fluid containing copper-alumina...

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Autores principales: Muhammad Jebran Khan, Balaganesh Duraisamy, Samina Zuhra, Rashid Nawaz, Kottakkaran Sooppy Nisar, Wasim Jamshed, I.S. Yahia
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Publicado: Elsevier 2021
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spelling oai:doaj.org-article:b45bdc4d963b476797ed339d1d662e462021-12-02T05:01:35ZNumerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method2214-157X10.1016/j.csite.2021.101673https://doaj.org/article/b45bdc4d963b476797ed339d1d662e462021-12-01T00:00:00Zhttp://www.sciencedirect.com/science/article/pii/S2214157X21008364https://doaj.org/toc/2214-157XHybrid nanofluids have generally been used to improve the applications heat transfer as a heat exchanger due to its significant thermos-physical properties compared to conventional fluid. In this article, 3D axis symmetric flow and heat dissipation over a hybrid nano fluid containing copper-alumina stays in the base liquid water are presented. This flow passes over the biaxial porous stretching/lowering sheet under the force of hot air and Cattaneo-Christov heat conduction, which is short for the (AMH–HNF–TCCHF) flow model. The partial differential equations of the proposed model are adjusted through a suitable similarity transformation that generates the ordinary differential system with physical variation. To analyse the physical variations, simulation of ODE systems is performed through a novel numerical technique named the “Modified New Iterative Method” (MNIM), which has been proved to be fast, convergent, and reliable. The results of physical variations in the stretching/shrinking parameter, mass flux, thermal radiation quantity, the thermal relaxation parameter and the Prandtl number in the velocity and energy field are shown in the graphs. This model emphasises the importance of study in potential medicinal fields, especially in 3D objects and cooling procedures in industries.Muhammad Jebran KhanBalaganesh DuraisamySamina ZuhraRashid NawazKottakkaran Sooppy NisarWasim JamshedI.S. YahiaElsevierarticleCatteneo- Christov heat flux modelStretching/shrinking sheetHybrid nanofluidNumerical iterative methodEngineering (General). Civil engineering (General)TA1-2040ENCase Studies in Thermal Engineering, Vol 28, Iss , Pp 101673- (2021)
institution DOAJ
collection DOAJ
language EN
topic Catteneo- Christov heat flux model
Stretching/shrinking sheet
Hybrid nanofluid
Numerical iterative method
Engineering (General). Civil engineering (General)
TA1-2040
spellingShingle Catteneo- Christov heat flux model
Stretching/shrinking sheet
Hybrid nanofluid
Numerical iterative method
Engineering (General). Civil engineering (General)
TA1-2040
Muhammad Jebran Khan
Balaganesh Duraisamy
Samina Zuhra
Rashid Nawaz
Kottakkaran Sooppy Nisar
Wasim Jamshed
I.S. Yahia
Numerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method
description Hybrid nanofluids have generally been used to improve the applications heat transfer as a heat exchanger due to its significant thermos-physical properties compared to conventional fluid. In this article, 3D axis symmetric flow and heat dissipation over a hybrid nano fluid containing copper-alumina stays in the base liquid water are presented. This flow passes over the biaxial porous stretching/lowering sheet under the force of hot air and Cattaneo-Christov heat conduction, which is short for the (AMH–HNF–TCCHF) flow model. The partial differential equations of the proposed model are adjusted through a suitable similarity transformation that generates the ordinary differential system with physical variation. To analyse the physical variations, simulation of ODE systems is performed through a novel numerical technique named the “Modified New Iterative Method” (MNIM), which has been proved to be fast, convergent, and reliable. The results of physical variations in the stretching/shrinking parameter, mass flux, thermal radiation quantity, the thermal relaxation parameter and the Prandtl number in the velocity and energy field are shown in the graphs. This model emphasises the importance of study in potential medicinal fields, especially in 3D objects and cooling procedures in industries.
format article
author Muhammad Jebran Khan
Balaganesh Duraisamy
Samina Zuhra
Rashid Nawaz
Kottakkaran Sooppy Nisar
Wasim Jamshed
I.S. Yahia
author_facet Muhammad Jebran Khan
Balaganesh Duraisamy
Samina Zuhra
Rashid Nawaz
Kottakkaran Sooppy Nisar
Wasim Jamshed
I.S. Yahia
author_sort Muhammad Jebran Khan
title Numerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method
title_short Numerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method
title_full Numerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method
title_fullStr Numerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method
title_full_unstemmed Numerical solution of Catteno-Christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method
title_sort numerical solution of catteno-christov heat flux model over stretching/shrinking hybrid nanofluid by new iterative method
publisher Elsevier
publishDate 2021
url https://doaj.org/article/b45bdc4d963b476797ed339d1d662e46
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AT saminazuhra numericalsolutionofcattenochristovheatfluxmodeloverstretchingshrinkinghybridnanofluidbynewiterativemethod
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