Darcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration
In the current work, we have investigated the flow past a semi-infinite porous solid media, after presenting a similarity transformation, governing equations mapped to a system of non-linear PDE. The flow of a dusty fluid and heat transfer through a porous medium have few applications, viz., the pol...
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2021
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oai:doaj.org-article:483998342bb34701a491f89d13c6dd9f2021-11-25T17:17:15ZDarcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration10.3390/computation91101182079-3197https://doaj.org/article/483998342bb34701a491f89d13c6dd9f2021-11-01T00:00:00Zhttps://www.mdpi.com/2079-3197/9/11/118https://doaj.org/toc/2079-3197In the current work, we have investigated the flow past a semi-infinite porous solid media, after presenting a similarity transformation, governing equations mapped to a system of non-linear PDE. The flow of a dusty fluid and heat transfer through a porous medium have few applications, viz., the polymer processing unit of a geophysical, allied area, and chemical engineering plant. Further, we had the option to get an exact analytical solution for the velocity to the equation that is non-linear. The highlight of the current work is the flow of hybrid dusty nanofluid due to Darcy porous media through linear thermal radiation with the assistance of an analytical process. The hybrid dusty nanofluid has significant features improving the heat transfer process and is extensively developed in manufacturing industrial uses. It was found that the basic similarity equations admit two phases for both stretching/shrinking surfaces. The existence of computation on velocity and temperature profile is presented graphically for different estimations of various physical parameters.K. N. SnehaU. S. MahabaleshwarRachid BennacerMohammed EL. GanaouiMDPI AGarticleDarcy-Brinkman numberhybrid nanofluiddusty fluidElectronic computers. Computer scienceQA75.5-76.95ENComputation, Vol 9, Iss 118, p 118 (2021) |
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Darcy-Brinkman number hybrid nanofluid dusty fluid Electronic computers. Computer science QA75.5-76.95 |
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Darcy-Brinkman number hybrid nanofluid dusty fluid Electronic computers. Computer science QA75.5-76.95 K. N. Sneha U. S. Mahabaleshwar Rachid Bennacer Mohammed EL. Ganaoui Darcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration |
| description |
In the current work, we have investigated the flow past a semi-infinite porous solid media, after presenting a similarity transformation, governing equations mapped to a system of non-linear PDE. The flow of a dusty fluid and heat transfer through a porous medium have few applications, viz., the polymer processing unit of a geophysical, allied area, and chemical engineering plant. Further, we had the option to get an exact analytical solution for the velocity to the equation that is non-linear. The highlight of the current work is the flow of hybrid dusty nanofluid due to Darcy porous media through linear thermal radiation with the assistance of an analytical process. The hybrid dusty nanofluid has significant features improving the heat transfer process and is extensively developed in manufacturing industrial uses. It was found that the basic similarity equations admit two phases for both stretching/shrinking surfaces. The existence of computation on velocity and temperature profile is presented graphically for different estimations of various physical parameters. |
| format |
article |
| author |
K. N. Sneha U. S. Mahabaleshwar Rachid Bennacer Mohammed EL. Ganaoui |
| author_facet |
K. N. Sneha U. S. Mahabaleshwar Rachid Bennacer Mohammed EL. Ganaoui |
| author_sort |
K. N. Sneha |
| title |
Darcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration |
| title_short |
Darcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration |
| title_full |
Darcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration |
| title_fullStr |
Darcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration |
| title_full_unstemmed |
Darcy Brinkman Equations for Hybrid Dusty Nanofluid Flow with Heat Transfer and Mass Transpiration |
| title_sort |
darcy brinkman equations for hybrid dusty nanofluid flow with heat transfer and mass transpiration |
| publisher |
MDPI AG |
| publishDate |
2021 |
| url |
https://doaj.org/article/483998342bb34701a491f89d13c6dd9f |
| work_keys_str_mv |
AT knsneha darcybrinkmanequationsforhybriddustynanofluidflowwithheattransferandmasstranspiration AT usmahabaleshwar darcybrinkmanequationsforhybriddustynanofluidflowwithheattransferandmasstranspiration AT rachidbennacer darcybrinkmanequationsforhybriddustynanofluidflowwithheattransferandmasstranspiration AT mohammedelganaoui darcybrinkmanequationsforhybriddustynanofluidflowwithheattransferandmasstranspiration |
| _version_ |
1718412526247477248 |