Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid

Heat transfer technologies are experiencing rapid expansion as a result of the demand for efficient heating and cooling systems in the automotive, chemical, and aerospace industries. Therefore, the current study peruses an inspection of mixed convective radiative Williamson flow close to a stagnatio...

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Main Authors: Boonsatit, Nattakan, Khan, Umair, Ishak, Anuar, Zaib, Aurang, Waini, Iskandar, M Sherif, El Sayed, Pop, Ioan, Jirawattanapanit, Anuwat
Format: Article
Language:English
Published: MDPI 2022
Online Access:http://eprints.utem.edu.my/id/eprint/26320/2/KHAN2022%20LUBRICANTS-10-00192-V2.PDF
http://eprints.utem.edu.my/id/eprint/26320/
https://www.mdpi.com/2075-4442/10/8/192
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spelling my.utem.eprints.263202023-03-03T16:07:00Z http://eprints.utem.edu.my/id/eprint/26320/ Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid Boonsatit, Nattakan Khan, Umair Ishak, Anuar Zaib, Aurang Waini, Iskandar M Sherif, El Sayed Pop, Ioan Jirawattanapanit, Anuwat Heat transfer technologies are experiencing rapid expansion as a result of the demand for efficient heating and cooling systems in the automotive, chemical, and aerospace industries. Therefore, the current study peruses an inspection of mixed convective radiative Williamson flow close to a stagnation point aggravated by a single nanoparticle (alumina) from a vertical flat plate with the impact of Hall. The convective heating of water conveying alumina (Al2O3) nanoparticles, as appropriate in engineering or industry, is investigated. Using pertinent similarity variables, the dominating equations are non-dimensionalized, and after that, via the bvp4c solver, they are numerically solved. We extensively explore the effects of many relevant parameters on axial velocity, transverse velocity, temperature profile, heat transfer, and drag force. In the opposing flow, there are two solutions seen; in the aiding flow, just one solution is found. In addition, the results designate that, due to nanofluid, the thickness of the velocity boundary layer decreases, and the thermal boundary layer width upsurges. The gradients for the branch of stable outcome escalate due to a higher Weissenberg parameter, while they decline for the branch of lower outcomes. Moreover, a magnetic field can be used to influence the flow and the properties of heat transfer. MDPI 2022-08 Article PeerReviewed text en http://eprints.utem.edu.my/id/eprint/26320/2/KHAN2022%20LUBRICANTS-10-00192-V2.PDF Boonsatit, Nattakan and Khan, Umair and Ishak, Anuar and Zaib, Aurang and Waini, Iskandar and M Sherif, El Sayed and Pop, Ioan and Jirawattanapanit, Anuwat (2022) Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid. Lubricants, 10 (8). 01-18. ISSN 2075-4442 https://www.mdpi.com/2075-4442/10/8/192 10.3390/lubricants10080192
institution Universiti Teknikal Malaysia Melaka
building UTEM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknikal Malaysia Melaka
content_source UTEM Institutional Repository
url_provider http://eprints.utem.edu.my/
language English
description Heat transfer technologies are experiencing rapid expansion as a result of the demand for efficient heating and cooling systems in the automotive, chemical, and aerospace industries. Therefore, the current study peruses an inspection of mixed convective radiative Williamson flow close to a stagnation point aggravated by a single nanoparticle (alumina) from a vertical flat plate with the impact of Hall. The convective heating of water conveying alumina (Al2O3) nanoparticles, as appropriate in engineering or industry, is investigated. Using pertinent similarity variables, the dominating equations are non-dimensionalized, and after that, via the bvp4c solver, they are numerically solved. We extensively explore the effects of many relevant parameters on axial velocity, transverse velocity, temperature profile, heat transfer, and drag force. In the opposing flow, there are two solutions seen; in the aiding flow, just one solution is found. In addition, the results designate that, due to nanofluid, the thickness of the velocity boundary layer decreases, and the thermal boundary layer width upsurges. The gradients for the branch of stable outcome escalate due to a higher Weissenberg parameter, while they decline for the branch of lower outcomes. Moreover, a magnetic field can be used to influence the flow and the properties of heat transfer.
format Article
author Boonsatit, Nattakan
Khan, Umair
Ishak, Anuar
Zaib, Aurang
Waini, Iskandar
M Sherif, El Sayed
Pop, Ioan
Jirawattanapanit, Anuwat
spellingShingle Boonsatit, Nattakan
Khan, Umair
Ishak, Anuar
Zaib, Aurang
Waini, Iskandar
M Sherif, El Sayed
Pop, Ioan
Jirawattanapanit, Anuwat
Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid
author_facet Boonsatit, Nattakan
Khan, Umair
Ishak, Anuar
Zaib, Aurang
Waini, Iskandar
M Sherif, El Sayed
Pop, Ioan
Jirawattanapanit, Anuwat
author_sort Boonsatit, Nattakan
title Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid
title_short Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid
title_full Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid
title_fullStr Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid
title_full_unstemmed Ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid
title_sort ramification of hall and mixed convective radiative flow towards a stagnation point into the motion of water conveying alumina nanoparticles past a flat vertical plate with a convective boundary condition: the case of non-newtonian williamson fluid
publisher MDPI
publishDate 2022
url http://eprints.utem.edu.my/id/eprint/26320/2/KHAN2022%20LUBRICANTS-10-00192-V2.PDF
http://eprints.utem.edu.my/id/eprint/26320/
https://www.mdpi.com/2075-4442/10/8/192
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score 13.211869