Sutterby fluid flow subject to homogeneous–heterogeneous reactions and nonlinear radiation

This paper addresses MHD Sutterby fluid flow by a rotating disk of variable thickness. Thermal radiation is nonlinear. Impact of homogeneous–heterogeneous reactions is also examined. For the development of convergent solution the homotopy concept is utilized. Skin friction coefficient, temperature,...

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Published inPhysica A Vol. 544; p. 123439
Main Authors Hayat, Tasawar, Masood, Faria, Qayyum, Sumaira, Alsaedi, Ahmed
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.04.2020
Subjects
Homogeneous–heterogeneous reactions
MHD
Nonlinear thermal radiation
Stretchable rotating disk
Sutterby fluid
Variable thickness
Variable thickness
MHD
Nonlinear thermal radiation
Homogeneous–heterogeneous reactions
Sutterby fluid
Stretchable rotating disk
Online AccessGet full text
ISSN0378-4371
1873-2119
DOI10.1016/j.physa.2019.123439

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Abstract This paper addresses MHD Sutterby fluid flow by a rotating disk of variable thickness. Thermal radiation is nonlinear. Impact of homogeneous–heterogeneous reactions is also examined. For the development of convergent solution the homotopy concept is utilized. Skin friction coefficient, temperature, velocity and Nusselt number are addressed. Radial, azimuthal and tangential velocities are enhanced by increasing the disk thickness. For larger disk thickness coefficient there is decay in skin friction. Nusselt number is enhanced for larger Prandtl number and radiation parameter. •MHD Sutterby fluid flow by a rotating disk of variable thickness is considered.•Thermal radiation is nonlinear.•Impact of homogeneous–heterogeneous reactions is also examined.•Tangential and radial velocities decay for larger (M) while both have increasing behavior for (n).•Fluid temperature decreases for Pr while reverse is seen for (R) and (θw).
AbstractList This paper addresses MHD Sutterby fluid flow by a rotating disk of variable thickness. Thermal radiation is nonlinear. Impact of homogeneous–heterogeneous reactions is also examined. For the development of convergent solution the homotopy concept is utilized. Skin friction coefficient, temperature, velocity and Nusselt number are addressed. Radial, azimuthal and tangential velocities are enhanced by increasing the disk thickness. For larger disk thickness coefficient there is decay in skin friction. Nusselt number is enhanced for larger Prandtl number and radiation parameter. •MHD Sutterby fluid flow by a rotating disk of variable thickness is considered.•Thermal radiation is nonlinear.•Impact of homogeneous–heterogeneous reactions is also examined.•Tangential and radial velocities decay for larger (M) while both have increasing behavior for (n).•Fluid temperature decreases for Pr while reverse is seen for (R) and (θw).
ArticleNumber 123439
Author Masood, Faria
Hayat, Tasawar
Qayyum, Sumaira
Alsaedi, Ahmed
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  givenname: Ahmed
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Keywords Variable thickness
MHD
Nonlinear thermal radiation
Homogeneous–heterogeneous reactions
Sutterby fluid
Stretchable rotating disk
Language English
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Snippet This paper addresses MHD Sutterby fluid flow by a rotating disk of variable thickness. Thermal radiation is nonlinear. Impact of homogeneous–heterogeneous...
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elsevier
SourceType Enrichment Source
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StartPage 123439
SubjectTerms Homogeneous–heterogeneous reactions
MHD
Nonlinear thermal radiation
Stretchable rotating disk
Sutterby fluid
Variable thickness
Title Sutterby fluid flow subject to homogeneous–heterogeneous reactions and nonlinear radiation
URI https://dx.doi.org/10.1016/j.physa.2019.123439
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