A non-Fourier heat and mass mathematical model for unsteady double diffusion flow with inclined radiative effects

Samina Batool; Kamel Al-Khaled; Sami Ullah Khan; Qazi Mahmood Ul-Hassan; Tasawar Abbas; M. Ijaz Khan; Kamel Guedri; Ahmed M. Galal

doi:10.1142/S0217979223500339

A non-Fourier heat and mass mathematical model for unsteady double diffusion flow with inclined radiative effects

Samina Batool, Kamel Al-Khaled, Sami Ullah Khan, Qazi Mahmood Ul-Hassan, Tasawar Abbas, M. Ijaz Khan^*, Kamel Guedri, Ahmed M. Galal

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

The double diffusion heat transfer phenomenon for the unsteady viscous fluid has been focused subject to the non-Fourier relations. The thermal radiation impact along the inclined direction has also been utilized. The non-Fourier analysis for the heating phenomenon is performed using the Cattaneo-Christov and Fick's mathematical models. The transformed systems due to similarity variables are analytically predicted via HAM scheme and also with the assistance of BVP4C solver. The convergence of the method to justify a solution is also observed. Also, the effect of involved physical parameters on the given model is explained through graphs and tables. The observations are compared with the available literature with a fine agreement. The numerical representation and quantitative analysis for drag force, heat transfer and mass transfer rates are worked out.

Original language	English
Article number	2350033
Journal	International Journal of Modern Physics B
DOIs	https://doi.org/10.1142/S0217979223500339
Publication status	Accepted/In press - 2022
Externally published	Yes

Keywords

double diffusion flow
heat transfer
homotopy analysis method
non-Fourier approach
Viscous flow

ASJC Scopus subject areas

Statistical and Nonlinear Physics
Condensed Matter Physics

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10.1142/S0217979223500339

Cite this

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title = "A non-Fourier heat and mass mathematical model for unsteady double diffusion flow with inclined radiative effects",

abstract = "The double diffusion heat transfer phenomenon for the unsteady viscous fluid has been focused subject to the non-Fourier relations. The thermal radiation impact along the inclined direction has also been utilized. The non-Fourier analysis for the heating phenomenon is performed using the Cattaneo-Christov and Fick's mathematical models. The transformed systems due to similarity variables are analytically predicted via HAM scheme and also with the assistance of BVP4C solver. The convergence of the method to justify a solution is also observed. Also, the effect of involved physical parameters on the given model is explained through graphs and tables. The observations are compared with the available literature with a fine agreement. The numerical representation and quantitative analysis for drag force, heat transfer and mass transfer rates are worked out.",

keywords = "double diffusion flow, heat transfer, homotopy analysis method, non-Fourier approach, Viscous flow",

author = "Samina Batool and Kamel Al-Khaled and Khan, {Sami Ullah} and Ul-Hassan, {Qazi Mahmood} and Tasawar Abbas and Khan, {M. Ijaz} and Kamel Guedri and Galal, {Ahmed M.}",

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doi = "10.1142/S0217979223500339",

language = "English",

journal = "International Journal of Modern Physics B",

issn = "0217-9792",

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T1 - A non-Fourier heat and mass mathematical model for unsteady double diffusion flow with inclined radiative effects

AU - Batool, Samina

AU - Al-Khaled, Kamel

AU - Khan, Sami Ullah

AU - Ul-Hassan, Qazi Mahmood

AU - Abbas, Tasawar

AU - Khan, M. Ijaz

AU - Guedri, Kamel

AU - Galal, Ahmed M.

PY - 2022

Y1 - 2022

N2 - The double diffusion heat transfer phenomenon for the unsteady viscous fluid has been focused subject to the non-Fourier relations. The thermal radiation impact along the inclined direction has also been utilized. The non-Fourier analysis for the heating phenomenon is performed using the Cattaneo-Christov and Fick's mathematical models. The transformed systems due to similarity variables are analytically predicted via HAM scheme and also with the assistance of BVP4C solver. The convergence of the method to justify a solution is also observed. Also, the effect of involved physical parameters on the given model is explained through graphs and tables. The observations are compared with the available literature with a fine agreement. The numerical representation and quantitative analysis for drag force, heat transfer and mass transfer rates are worked out.

AB - The double diffusion heat transfer phenomenon for the unsteady viscous fluid has been focused subject to the non-Fourier relations. The thermal radiation impact along the inclined direction has also been utilized. The non-Fourier analysis for the heating phenomenon is performed using the Cattaneo-Christov and Fick's mathematical models. The transformed systems due to similarity variables are analytically predicted via HAM scheme and also with the assistance of BVP4C solver. The convergence of the method to justify a solution is also observed. Also, the effect of involved physical parameters on the given model is explained through graphs and tables. The observations are compared with the available literature with a fine agreement. The numerical representation and quantitative analysis for drag force, heat transfer and mass transfer rates are worked out.

KW - double diffusion flow

KW - heat transfer

KW - homotopy analysis method

KW - non-Fourier approach

KW - Viscous flow

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JF - International Journal of Modern Physics B

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A non-Fourier heat and mass mathematical model for unsteady double diffusion flow with inclined radiative effects

Abstract

Keywords

ASJC Scopus subject areas

Access to Document

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