Unsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink

In the field of nano-composites, hybrid nano-fluids have noteworthy applications in aerospace, energy materials, thermal sensors, antifouling, etc. because of their ability to produce higher thermal conductivity than conventional nanofluids. Different combinations of nanocomposites have been found i...

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Autores principales: Iftikhar Ahmad, Muhammad Faisal, Qazi Zan-Ul-Abadin, Tariq Javed, Loganathan Karuppusamy
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Lenguaje:EN
Publicado: Taylor & Francis Group 2021
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spelling oai:doaj.org-article:d2fdab57ae3249afa659887497ae8bec2021-11-26T11:19:49ZUnsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink2055-03242055-033210.1080/20550324.2021.2008208https://doaj.org/article/d2fdab57ae3249afa659887497ae8bec2021-11-01T00:00:00Zhttp://dx.doi.org/10.1080/20550324.2021.2008208https://doaj.org/toc/2055-0324https://doaj.org/toc/2055-0332In the field of nano-composites, hybrid nano-fluids have noteworthy applications in aerospace, energy materials, thermal sensors, antifouling, etc. because of their ability to produce higher thermal conductivity than conventional nanofluids. Different combinations of nanocomposites have been found in the literature to develop the suitable hybrid-mixture, but no study has been found yet about the combined influence of ceria and zinc-oxide nanocomposites in the host liquid. In this article, unsteady 3 D transport of water driven hybrid nano-fluid with the consequences of brick shaped nanocomposites (ceria; and zinc oxide; ) has deliberated with the thermal link of heat source/sink. Variable thermal conditions have been supplied at the surface with the effect of a magnetic environment. Similarity relations have been used to articulate the transport equations into solvable forms and then solved numerically via Keller-Box method. Nusslet number and skin-friction coefficients have also plotted with the wide ranges of involved parameters. Thermal setup has also briefly been discussed with the non-uniformity of surface temperature. Rate of heat transfer has significantly improved with the amounts of ceria (1 wt% to 10 wt%) and zinc-oxide (1 wt% to 10 wt%) nanocomposites. The Nusslet number is reported in the range of 4.0 to 4.8 with the increasing amount of from −0.6 to −0.2, whereas it is reported in the range of 3.1 to 3.9 with the varying amount of from 0.2 to 0.6. Rate of heat transfer is observed higher for zinc-oxide nanoparticles as compared to ceria nanoparticles.Iftikhar AhmadMuhammad FaisalQazi Zan-Ul-AbadinTariq JavedLoganathan KaruppusamyTaylor & Francis Grouparticlebrick shaped nanocompositesceriaheat source/sinkhybrid nanofluidmhdunsteady 3d dynamicsvariable thermal conditionszinc-oxideMaterials of engineering and construction. Mechanics of materialsTA401-492Polymers and polymer manufactureTP1080-1185ENNanocomposites, Vol 0, Iss 0, Pp 1-15 (2021)
institution DOAJ
collection DOAJ
language EN
topic brick shaped nanocomposites
ceria
heat source/sink
hybrid nanofluid
mhd
unsteady 3d dynamics
variable thermal conditions
zinc-oxide
Materials of engineering and construction. Mechanics of materials
TA401-492
Polymers and polymer manufacture
TP1080-1185
spellingShingle brick shaped nanocomposites
ceria
heat source/sink
hybrid nanofluid
mhd
unsteady 3d dynamics
variable thermal conditions
zinc-oxide
Materials of engineering and construction. Mechanics of materials
TA401-492
Polymers and polymer manufacture
TP1080-1185
Iftikhar Ahmad
Muhammad Faisal
Qazi Zan-Ul-Abadin
Tariq Javed
Loganathan Karuppusamy
Unsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink
description In the field of nano-composites, hybrid nano-fluids have noteworthy applications in aerospace, energy materials, thermal sensors, antifouling, etc. because of their ability to produce higher thermal conductivity than conventional nanofluids. Different combinations of nanocomposites have been found in the literature to develop the suitable hybrid-mixture, but no study has been found yet about the combined influence of ceria and zinc-oxide nanocomposites in the host liquid. In this article, unsteady 3 D transport of water driven hybrid nano-fluid with the consequences of brick shaped nanocomposites (ceria; and zinc oxide; ) has deliberated with the thermal link of heat source/sink. Variable thermal conditions have been supplied at the surface with the effect of a magnetic environment. Similarity relations have been used to articulate the transport equations into solvable forms and then solved numerically via Keller-Box method. Nusslet number and skin-friction coefficients have also plotted with the wide ranges of involved parameters. Thermal setup has also briefly been discussed with the non-uniformity of surface temperature. Rate of heat transfer has significantly improved with the amounts of ceria (1 wt% to 10 wt%) and zinc-oxide (1 wt% to 10 wt%) nanocomposites. The Nusslet number is reported in the range of 4.0 to 4.8 with the increasing amount of from −0.6 to −0.2, whereas it is reported in the range of 3.1 to 3.9 with the varying amount of from 0.2 to 0.6. Rate of heat transfer is observed higher for zinc-oxide nanoparticles as compared to ceria nanoparticles.
format article
author Iftikhar Ahmad
Muhammad Faisal
Qazi Zan-Ul-Abadin
Tariq Javed
Loganathan Karuppusamy
author_facet Iftikhar Ahmad
Muhammad Faisal
Qazi Zan-Ul-Abadin
Tariq Javed
Loganathan Karuppusamy
author_sort Iftikhar Ahmad
title Unsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink
title_short Unsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink
title_full Unsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink
title_fullStr Unsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink
title_full_unstemmed Unsteady 3D heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink
title_sort unsteady 3d heat transport in hybrid nanofluid containing brick shaped ceria and zinc-oxide nanocomposites with heat source/sink
publisher Taylor & Francis Group
publishDate 2021
url https://doaj.org/article/d2fdab57ae3249afa659887497ae8bec
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AT qazizanulabadin unsteady3dheattransportinhybridnanofluidcontainingbrickshapedceriaandzincoxidenanocompositeswithheatsourcesink
AT tariqjaved unsteady3dheattransportinhybridnanofluidcontainingbrickshapedceriaandzincoxidenanocompositeswithheatsourcesink
AT loganathankaruppusamy unsteady3dheattransportinhybridnanofluidcontainingbrickshapedceriaandzincoxidenanocompositeswithheatsourcesink
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