Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge

El Sayed M. Tag El Din; Tanveer Sajid; Wasim Jamshed; Syed Zahir Hussain Shah; Mohamed R. Eid; Assad Ayub; Kamel Guedri; Manuel Sánchez-Chero; José Antonio Sánchez Chero; Gilberto Carrión Barco; Gisella Luisa Elena Maquen-Niño

doi:10.1515/phys-2022-0216

Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge

El Sayed M. Tag El Din, Tanveer Sajid, Wasim Jamshed, Syed Zahir Hussain Shah, Mohamed R. Eid, Assad Ayub, Kamel Guedri, Manuel Sánchez-Chero, José Antonio Sánchez Chero, Gilberto Carrión Barco, Gisella Luisa Elena Maquen-Niño

Ingeniería en Computación e Informática

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

7 Citas (Scopus)

Resumen

This demonstration of study focalizes the melting transport and inclined magnetizing effect of cross fluid with infinite shear rate viscosity along the Skan-Falkner wedge. Transport of energy analysis is brought through the melting process and velocity distribution is numerically achieved under the influence of the inclined magnetic dipole effect. Moreover, this study brings out the numerical effect of the process of thermophoresis diffusion and Brownian motion. The infinite shear rate of viscosity model of cross fluid reveals the set of partial differential equations (PDEs). Similarity transformation of variables converts the PDEs system into nonlinear ordinary differential equations (ODEs). Furthermore, a numerical bvp4c process is imposed on these resultant ODEs for the pursuit of a numerical solution. From the debate, it is concluded that melting process cases boost the velocity of fluid and velocity ratio parameter. The augmentation of the minimum value of energy needed to activate or energize the molecules or atoms to activate the chemical reaction boosts the concentricity.

Idioma original	Inglés
Páginas (desde-hasta)	1233-1249
Número de páginas	17
Publicación	Open Physics
Volumen	20
N.º	1
DOI	https://doi.org/10.1515/phys-2022-0216
Estado	Publicada - 1 ene. 2022

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© 2022 the author(s), published by De Gruyter.

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Tag El Din, E. S. M., Sajid, T., Jamshed, W., Shah, S. Z. H., Eid, M. R., Ayub, A., Guedri, K., Sánchez-Chero, M., Chero, J. A. S., Barco, G. C., & Maquen-Niño, G. L. E. (2022). Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge. Open Physics, 20(1), 1233-1249. https://doi.org/10.1515/phys-2022-0216

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title = "Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge",

abstract = "This demonstration of study focalizes the melting transport and inclined magnetizing effect of cross fluid with infinite shear rate viscosity along the Skan-Falkner wedge. Transport of energy analysis is brought through the melting process and velocity distribution is numerically achieved under the influence of the inclined magnetic dipole effect. Moreover, this study brings out the numerical effect of the process of thermophoresis diffusion and Brownian motion. The infinite shear rate of viscosity model of cross fluid reveals the set of partial differential equations (PDEs). Similarity transformation of variables converts the PDEs system into nonlinear ordinary differential equations (ODEs). Furthermore, a numerical bvp4c process is imposed on these resultant ODEs for the pursuit of a numerical solution. From the debate, it is concluded that melting process cases boost the velocity of fluid and velocity ratio parameter. The augmentation of the minimum value of energy needed to activate or energize the molecules or atoms to activate the chemical reaction boosts the concentricity.",

keywords = "2-D cross fluid, Brownian motion, inclined magnetized flow, infinite shear rate viscosity, melting process of energy, thermophoresis diffusion",

author = "{Tag El Din}, {El Sayed M.} and Tanveer Sajid and Wasim Jamshed and Shah, {Syed Zahir Hussain} and Eid, {Mohamed R.} and Assad Ayub and Kamel Guedri and Manuel S{\'a}nchez-Chero and Chero, {Jos{\'e} Antonio S{\'a}nchez} and Barco, {Gilberto Carri{\'o}n} and Maquen-Ni{\~n}o, {Gisella Luisa Elena}",

note = "Publisher Copyright: {\textcopyright} 2022 the author(s), published by De Gruyter.",

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doi = "10.1515/phys-2022-0216",

language = "English",

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AU - Tag El Din, El Sayed M.

AU - Sajid, Tanveer

AU - Jamshed, Wasim

AU - Shah, Syed Zahir Hussain

AU - Eid, Mohamed R.

AU - Ayub, Assad

AU - Guedri, Kamel

AU - Sánchez-Chero, Manuel

AU - Chero, José Antonio Sánchez

AU - Barco, Gilberto Carrión

AU - Maquen-Niño, Gisella Luisa Elena

PY - 2022/1/1

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N2 - This demonstration of study focalizes the melting transport and inclined magnetizing effect of cross fluid with infinite shear rate viscosity along the Skan-Falkner wedge. Transport of energy analysis is brought through the melting process and velocity distribution is numerically achieved under the influence of the inclined magnetic dipole effect. Moreover, this study brings out the numerical effect of the process of thermophoresis diffusion and Brownian motion. The infinite shear rate of viscosity model of cross fluid reveals the set of partial differential equations (PDEs). Similarity transformation of variables converts the PDEs system into nonlinear ordinary differential equations (ODEs). Furthermore, a numerical bvp4c process is imposed on these resultant ODEs for the pursuit of a numerical solution. From the debate, it is concluded that melting process cases boost the velocity of fluid and velocity ratio parameter. The augmentation of the minimum value of energy needed to activate or energize the molecules or atoms to activate the chemical reaction boosts the concentricity.

AB - This demonstration of study focalizes the melting transport and inclined magnetizing effect of cross fluid with infinite shear rate viscosity along the Skan-Falkner wedge. Transport of energy analysis is brought through the melting process and velocity distribution is numerically achieved under the influence of the inclined magnetic dipole effect. Moreover, this study brings out the numerical effect of the process of thermophoresis diffusion and Brownian motion. The infinite shear rate of viscosity model of cross fluid reveals the set of partial differential equations (PDEs). Similarity transformation of variables converts the PDEs system into nonlinear ordinary differential equations (ODEs). Furthermore, a numerical bvp4c process is imposed on these resultant ODEs for the pursuit of a numerical solution. From the debate, it is concluded that melting process cases boost the velocity of fluid and velocity ratio parameter. The augmentation of the minimum value of energy needed to activate or energize the molecules or atoms to activate the chemical reaction boosts the concentricity.

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KW - Brownian motion

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KW - thermophoresis diffusion

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Cross electromagnetic nanofluid flow examination with infinite shear rate viscosity and melting heat through Skan-Falkner wedge

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