Numerical computation of dufour and soret effects on radiated material on a porous stretching surface with temperature-dependent thermal conductivity

Tahir Naseem; Umar Nazir; Essam R. El-Zahar; Ahmed M. Algelany; Muhammad Sohail

doi:10.3390/FLUIDS6060196

Numerical computation of dufour and soret effects on radiated material on a porous stretching surface with temperature-dependent thermal conductivity

Tahir Naseem
, Umar Nazir
, Essam R. El-Zahar
, Ahmed M. Algelany
, Muhammad Sohail

Mathematics

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

13 Scopus citations

Abstract

The current research is prepared to address the transport phenomenon in a hydro-magnetized flow model on a porous stretching sheet. Mass and heat transport are modeled via temperature dependent models of thermal conductivity and diffusion coefficients. Accordingly, the involvement of radiation, chemical reaction, the Dufour effect, and the Soret effect are involved. The flow presenting expression has been modeled via boundary layer approximation and the flow is produced due to the experimental stretching sheet. The governing equations have been approximated numerically via shooting method. The efficiency of the scheme is established by including the comparative study. Moreover, a decline in the velocity field is recorded against the escalating values of the porosity parameter and the magnetic parameter.

Original language	English
Article number	196
Journal	Fluids
Volume	6
Issue number	6
DOIs	https://doi.org/10.3390/FLUIDS6060196
State	Published - Jun 2021

Keywords

Boundary layer theory
Nusselt number
Porous medium
Radiated heat flux
Shooting method
Stretching sheet

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10.3390/FLUIDS6060196

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title = "Numerical computation of dufour and soret effects on radiated material on a porous stretching surface with temperature-dependent thermal conductivity",

abstract = "The current research is prepared to address the transport phenomenon in a hydro-magnetized flow model on a porous stretching sheet. Mass and heat transport are modeled via temperature dependent models of thermal conductivity and diffusion coefficients. Accordingly, the involvement of radiation, chemical reaction, the Dufour effect, and the Soret effect are involved. The flow presenting expression has been modeled via boundary layer approximation and the flow is produced due to the experimental stretching sheet. The governing equations have been approximated numerically via shooting method. The efficiency of the scheme is established by including the comparative study. Moreover, a decline in the velocity field is recorded against the escalating values of the porosity parameter and the magnetic parameter.",

keywords = "Boundary layer theory, Nusselt number, Porous medium, Radiated heat flux, Shooting method, Stretching sheet",

author = "Tahir Naseem and Umar Nazir and El-Zahar, \{Essam R.\} and Algelany, \{Ahmed M.\} and Muhammad Sohail",

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T1 - Numerical computation of dufour and soret effects on radiated material on a porous stretching surface with temperature-dependent thermal conductivity

AU - Naseem, Tahir

AU - Nazir, Umar

AU - El-Zahar, Essam R.

AU - Algelany, Ahmed M.

AU - Sohail, Muhammad

PY - 2021/6

Y1 - 2021/6

N2 - The current research is prepared to address the transport phenomenon in a hydro-magnetized flow model on a porous stretching sheet. Mass and heat transport are modeled via temperature dependent models of thermal conductivity and diffusion coefficients. Accordingly, the involvement of radiation, chemical reaction, the Dufour effect, and the Soret effect are involved. The flow presenting expression has been modeled via boundary layer approximation and the flow is produced due to the experimental stretching sheet. The governing equations have been approximated numerically via shooting method. The efficiency of the scheme is established by including the comparative study. Moreover, a decline in the velocity field is recorded against the escalating values of the porosity parameter and the magnetic parameter.

AB - The current research is prepared to address the transport phenomenon in a hydro-magnetized flow model on a porous stretching sheet. Mass and heat transport are modeled via temperature dependent models of thermal conductivity and diffusion coefficients. Accordingly, the involvement of radiation, chemical reaction, the Dufour effect, and the Soret effect are involved. The flow presenting expression has been modeled via boundary layer approximation and the flow is produced due to the experimental stretching sheet. The governing equations have been approximated numerically via shooting method. The efficiency of the scheme is established by including the comparative study. Moreover, a decline in the velocity field is recorded against the escalating values of the porosity parameter and the magnetic parameter.

KW - Boundary layer theory

KW - Nusselt number

KW - Porous medium

KW - Radiated heat flux

KW - Shooting method

KW - Stretching sheet

UR - https://www.scopus.com/pages/publications/85108262851

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DO - 10.3390/FLUIDS6060196

M3 - Article

AN - SCOPUS:85108262851

SN - 2311-5521

VL - 6

JO - Fluids

JF - Fluids

IS - 6

M1 - 196

ER -

Numerical computation of dufour and soret effects on radiated material on a porous stretching surface with temperature-dependent thermal conductivity

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