Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge
Oil extraction, renewable energy, and biological heat transfer are the major applications of radiative Carreau nanofluid flow in the existence of microorganisms moving around a permeable wedge. This work examines the time-dependent flowing of two-phase Carreau nanofluid containing gyrostatic motile...
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| Format: | Article |
| Language: | English |
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De Gruyter
2025-03-01
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| Series: | Nanotechnology Reviews |
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| Online Access: | https://doi.org/10.1515/ntrev-2025-0146 |
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| author | Elsaid Essam M. El-Aziz Mohamed Abd Alruwaili Amani S. Eid Mohamed R. |
| author_facet | Elsaid Essam M. El-Aziz Mohamed Abd Alruwaili Amani S. Eid Mohamed R. |
| author_sort | Elsaid Essam M. |
| collection | DOAJ |
| description | Oil extraction, renewable energy, and biological heat transfer are the major applications of radiative Carreau nanofluid flow in the existence of microorganisms moving around a permeable wedge. This work examines the time-dependent flowing of two-phase Carreau nanofluid containing gyrostatic motile bacteria via permeable oblique wedge in the existence of heat source (sink) and thermal radiation. Magnetoelectric effect and yield stress on the flow motion of Carreau nanofluid are considered, as Carreau nanofluid is most suitable for representing different types of physics problems because it can disclose the rheology of liquids with short-chain suspension molecules and fluid crystals and because of its many uses in detergents and blood mixing, biological and medical operations. Appropriate similarity conversions are used to produce equations characterizing the system in a nondimensional mathematical model, which are subsequently resolved computationally using Runge-Kutta methodology based on the shooting approach. Attendance of yield stress boosts the surface frictional force, upsurges rates of heat and mass transfers of nanofluid, and maintains the density of bacteria significantly. Magnetoelectric effect also diminishes the rates of heat and mass transfers and increases the density of microorganisms in the nanofluid, which is beneficial for its uses. Yield stress is the greatest way to increase heat transfer rates in this nanofluid for industrial cooling. Magnetoelectric action and yield stress maintain microbe density, making it valuable for medicinal and biological procedures using useful bacteria. |
| format | Article |
| id | doaj-art-40d8941b36bf42a98da64ac2c68accd3 |
| institution | Kabale University |
| issn | 2191-9097 |
| language | English |
| publishDate | 2025-03-01 |
| publisher | De Gruyter |
| record_format | Article |
| series | Nanotechnology Reviews |
| spelling | doaj-art-40d8941b36bf42a98da64ac2c68accd32025-08-20T03:41:01ZengDe GruyterNanotechnology Reviews2191-90972025-03-0114124810.1515/ntrev-2025-0146Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedgeElsaid Essam M.0El-Aziz Mohamed Abd1Alruwaili Amani S.2Eid Mohamed R.3Department of Mathematics, College of Science, University of Bisha, P.O. Box 551, Bisha, 61922, Saudi ArabiaDepartment of Mathematics, Faculty of Science, Helwan University, Helwan-Cairo, 11795, EgyptDepartment of Physics, College of Science, Northern Border University, Arar, 1321, Saudi ArabiaCenter for Scientific Research and Entrepreneurship, Northern Border University, Arar, 73213, Saudi ArabiaOil extraction, renewable energy, and biological heat transfer are the major applications of radiative Carreau nanofluid flow in the existence of microorganisms moving around a permeable wedge. This work examines the time-dependent flowing of two-phase Carreau nanofluid containing gyrostatic motile bacteria via permeable oblique wedge in the existence of heat source (sink) and thermal radiation. Magnetoelectric effect and yield stress on the flow motion of Carreau nanofluid are considered, as Carreau nanofluid is most suitable for representing different types of physics problems because it can disclose the rheology of liquids with short-chain suspension molecules and fluid crystals and because of its many uses in detergents and blood mixing, biological and medical operations. Appropriate similarity conversions are used to produce equations characterizing the system in a nondimensional mathematical model, which are subsequently resolved computationally using Runge-Kutta methodology based on the shooting approach. Attendance of yield stress boosts the surface frictional force, upsurges rates of heat and mass transfers of nanofluid, and maintains the density of bacteria significantly. Magnetoelectric effect also diminishes the rates of heat and mass transfers and increases the density of microorganisms in the nanofluid, which is beneficial for its uses. Yield stress is the greatest way to increase heat transfer rates in this nanofluid for industrial cooling. Magnetoelectric action and yield stress maintain microbe density, making it valuable for medicinal and biological procedures using useful bacteria.https://doi.org/10.1515/ntrev-2025-0146carreau nanofluidmagnetoelectric effectbio-convectionviscous dissipationjoule heatingyield stress |
| spellingShingle | Elsaid Essam M. El-Aziz Mohamed Abd Alruwaili Amani S. Eid Mohamed R. Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge Nanotechnology Reviews carreau nanofluid magnetoelectric effect bio-convection viscous dissipation joule heating yield stress |
| title | Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge |
| title_full | Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge |
| title_fullStr | Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge |
| title_full_unstemmed | Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge |
| title_short | Physical aspects of radiative Carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge |
| title_sort | physical aspects of radiative carreau nanofluid flow with motile microorganisms movement under yield stress via oblique penetrable wedge |
| topic | carreau nanofluid magnetoelectric effect bio-convection viscous dissipation joule heating yield stress |
| url | https://doi.org/10.1515/ntrev-2025-0146 |
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