Forced convective tangent hyperbolic nanofluid flow subject to heat source/sink and Lorentz force over a permeable wedge: Numerical exploration

The magnetohydrodynamics tangent hyperbolic nanofluid (THNF) flow with the mutual impact of melting heat transfer and wedge angle over a permeable wedge is investigated numerically in the present study. Electronic devices generate excessive heat during operations, so THNF is often employed to regula...

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Published in	Nanotechnology reviews (Berlin) Vol. 13; no. 1; pp. 170664 - 89
Main Authors	Alqahtani, Aisha M., Bilal, Muhammad, Riaz, Muhammad Bilal, Chammam, Wathek, Shafi, Jana, Rahman, Mati ur, Adnan
Format	Journal Article
Language	English
Published	Berlin De Gruyter 18.05.2024 Walter de Gruyter GmbH
Subjects	Charged particles Computer engineering Computer science Continuation methods Electronic equipment exponential heat source/sink Fluid flow Heat Heat transfer Lorentz force Magnetic fields Magnetohydrodynamics Mathematics Nanofluids Nuclear energy Nuclear power plants numerical approach Overheating Permeability permeable wedge Radiation Reynolds number Shearing Skin friction tangent hyperbolic nanofluid Thermal radiation
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Abstract	The magnetohydrodynamics tangent hyperbolic nanofluid (THNF) flow with the mutual impact of melting heat transfer and wedge angle over a permeable wedge is investigated numerically in the present study. Electronic devices generate excessive heat during operations, so THNF is often employed to regulate them. THNF has the ability to neutralize heat with greater efficacy, thereby reducing the probability of overheating. The influence of thermal radiation, Soret and Dufour, and heat source/sink is also observed on the fluid flow. The modeled equations are simplified to the lowest order through the similarity conversion. The obtained set of dimensionless equations is further calculated numerically by employing the parametric continuation method. The computational findings of the present study are compared to the published results for accuracy purposes. It has been detected that the results are precise and reputable. Moreover, from the graphical results, it has been perceived that the effect of permeability factor ( ) reduces the fluid flow. The rising effect of wedge angle factor enhances the energy dissemination rate and shearing stress; however the augmentation of Weissenberg number drops skin friction and energy transference rate.
AbstractList	The magnetohydrodynamics tangent hyperbolic nanofluid (THNF) flow with the mutual impact of melting heat transfer and wedge angle over a permeable wedge is investigated numerically in the present study. Electronic devices generate excessive heat during operations, so THNF is often employed to regulate them. THNF has the ability to neutralize heat with greater efficacy, thereby reducing the probability of overheating. The influence of thermal radiation, Soret and Dufour, and heat source/sink is also observed on the fluid flow. The modeled equations are simplified to the lowest order through the similarity conversion. The obtained set of dimensionless equations is further calculated numerically by employing the parametric continuation method. The computational findings of the present study are compared to the published results for accuracy purposes. It has been detected that the results are precise and reputable. Moreover, from the graphical results, it has been perceived that the effect of permeability factor (K p) reduces the fluid flow. The rising effect of wedge angle factor enhances the energy dissemination rate and shearing stress; however the augmentation of Weissenberg number drops skin friction and energy transference rate. The magnetohydrodynamics tangent hyperbolic nanofluid (THNF) flow with the mutual impact of melting heat transfer and wedge angle over a permeable wedge is investigated numerically in the present study. Electronic devices generate excessive heat during operations, so THNF is often employed to regulate them. THNF has the ability to neutralize heat with greater efficacy, thereby reducing the probability of overheating. The influence of thermal radiation, Soret and Dufour, and heat source/sink is also observed on the fluid flow. The modeled equations are simplified to the lowest order through the similarity conversion. The obtained set of dimensionless equations is further calculated numerically by employing the parametric continuation method. The computational findings of the present study are compared to the published results for accuracy purposes. It has been detected that the results are precise and reputable. Moreover, from the graphical results, it has been perceived that the effect of permeability factor (Kp) reduces the fluid flow. The rising effect of wedge angle factor enhances the energy dissemination rate and shearing stress; however the augmentation of Weissenberg number drops skin friction and energy transference rate. The magnetohydrodynamics tangent hyperbolic nanofluid (THNF) flow with the mutual impact of melting heat transfer and wedge angle over a permeable wedge is investigated numerically in the present study. Electronic devices generate excessive heat during operations, so THNF is often employed to regulate them. THNF has the ability to neutralize heat with greater efficacy, thereby reducing the probability of overheating. The influence of thermal radiation, Soret and Dufour, and heat source/sink is also observed on the fluid flow. The modeled equations are simplified to the lowest order through the similarity conversion. The obtained set of dimensionless equations is further calculated numerically by employing the parametric continuation method. The computational findings of the present study are compared to the published results for accuracy purposes. It has been detected that the results are precise and reputable. Moreover, from the graphical results, it has been perceived that the effect of permeability factor ( ) reduces the fluid flow. The rising effect of wedge angle factor enhances the energy dissemination rate and shearing stress; however the augmentation of Weissenberg number drops skin friction and energy transference rate.
Author	Alqahtani, Aisha M. Chammam, Wathek Bilal, Muhammad Shafi, Jana Rahman, Mati ur Adnan Riaz, Muhammad Bilal
Author_xml	– sequence: 1 givenname: Aisha M. surname: Alqahtani fullname: Alqahtani, Aisha M. organization: Department of Mathematical Sciences, College of Science, Princess Nourah bint Abdulrahman University, P. O. Box 84428, Riyadh, 11671, Saudi Arabia – sequence: 2 givenname: Muhammad surname: Bilal fullname: Bilal, Muhammad email: bilalchd345@gmail.com organization: Sheikh Taimur Academic Block-II, Department of Mathematics, University of Peshawar, 25120, Khyber Pakhtunkhwa, Pakistan – sequence: 3 givenname: Muhammad Bilal surname: Riaz fullname: Riaz, Muhammad Bilal organization: ITInnovations, VSB–Technical University of Ostrava, Ostrava, Czech Republic – sequence: 4 givenname: Wathek surname: Chammam fullname: Chammam, Wathek email: w.chammam@mu.edu.sa organization: Department of Mathematics, College of Science, Majmaah University, Al-Majmaah, 11952, Saudi Arabia – sequence: 5 givenname: Jana surname: Shafi fullname: Shafi, Jana organization: Department of Computer Engineering and Information, College of Engineering in Wadi Alddawasir, Prince Sattam Bin Abdulaziz University, Wadi Ad-Dawasir, 11991, Saudi Arabia – sequence: 6 givenname: Mati ur surname: Rahman fullname: Rahman, Mati ur organization: Department of Computer Science and Mathematics, Lebanese American University, Byblos, Lebanon – sequence: 7 surname: Adnan fullname: Adnan organization: Department of Mathematics, Mohi-ud-Din Islamic University, Nerian Sharif, AJ and K, 12080, Pakistan
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Snippet	The magnetohydrodynamics tangent hyperbolic nanofluid (THNF) flow with the mutual impact of melting heat transfer and wedge angle over a permeable wedge is...
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SubjectTerms	Charged particles Computer engineering Computer science Continuation methods Electronic equipment exponential heat source/sink Fluid flow Heat Heat transfer Lorentz force Magnetic fields Magnetohydrodynamics Mathematics Nanofluids Nuclear energy Nuclear power plants numerical approach Overheating Permeability permeable wedge Radiation Reynolds number Shearing Skin friction tangent hyperbolic nanofluid Thermal radiation
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Title	Forced convective tangent hyperbolic nanofluid flow subject to heat source/sink and Lorentz force over a permeable wedge: Numerical exploration
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