Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface

In the current research, a thorough examination unfolds concerning the attributes of magnetohydrodynamic (MHD) boundary layer flow and heat transfer inherent to nanoliquids derived from Sisko Al2 O3-Eg and TiO2-Eg compositions. Such nanoliquids are subjected to an extending surface. Consideration is...

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Main Authors: Jyothi, K., Dasore, Abhishek, Ganapati, R., Shareef, Sk. Mohammad, Chamkha, Ali J., Prasad, V. Raghavendra
Format: Article
Language:English
Published: Tech Science Press 2024
Online Access:http://psasir.upm.edu.my/id/eprint/112035/1/112035.pdf
http://psasir.upm.edu.my/id/eprint/112035/
https://doi.org/10.32604/fhmt.2024.046891
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Institution: Universiti Putra Malaysia
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spelling my.upm.eprints.1120352024-10-28T07:20:15Z http://psasir.upm.edu.my/id/eprint/112035/ Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface Jyothi, K. Dasore, Abhishek Ganapati, R. Shareef, Sk. Mohammad Chamkha, Ali J. Prasad, V. Raghavendra In the current research, a thorough examination unfolds concerning the attributes of magnetohydrodynamic (MHD) boundary layer flow and heat transfer inherent to nanoliquids derived from Sisko Al2 O3-Eg and TiO2-Eg compositions. Such nanoliquids are subjected to an extending surface. Consideration is duly given to slip boundary conditions, as well as the effects stemming from variable viscosity and variable thermal conductivity. The analytical approach applied involves the application of suitable similarity transformations. These conversions serve to transform the initial set of complex nonlinear partial differential equations into a more manageable assembly of ordinary differential equations. Through the utilization of the FEM, these reformulated equations are solved, considering the specified boundary conditions. The outcomes attained are graphically depicted by means of plots and tables. These visual aids facilitate a comprehensive exploration of how diverse parameters exert influence over the distributions of velocity, temperature, and concentration. Furthermore, detailed scrutiny is directed towards the fluctuations characterizing pivotal parameters, viz., Nusselt number, skin-friction coefficient, and Sherwood number. It is identified that the Nusselt number showcases a diminishing trend coinciding with increasing values of the volume fraction parameter (φ). This trend remains consistent regardless of whether the nanoliquid under consideration is Al2O3-Eg or TiO2-Eg based. In contrast, both the skin-friction coefficient and Sherwood number assume lower values as the volume fraction parameter (φ) escalates. This pattern remains congruent across both classifications of nanoliquids. The findings of the study impart valuable insights into the complex interplay governing the characteristics of HMT pertaining to Sisko Al2 O3-Eg and TiO2-Eg nanoliquids along an extending surface. © 2024, Tech Science Press. All rights reserved. Tech Science Press 2024 Article PeerReviewed text en cc_by_4 http://psasir.upm.edu.my/id/eprint/112035/1/112035.pdf Jyothi, K. and Dasore, Abhishek and Ganapati, R. and Shareef, Sk. Mohammad and Chamkha, Ali J. and Prasad, V. Raghavendra (2024) Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface. Frontiers in Heat and Mass Transfer, 22 (1). pp. 79-105. ISSN 2151-8629 https://doi.org/10.32604/fhmt.2024.046891 10.32604/fhmt.2024.046891
institution Universiti Putra Malaysia
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country Malaysia
content_provider Universiti Putra Malaysia
content_source UPM Institutional Repository
url_provider http://psasir.upm.edu.my/
language English
description In the current research, a thorough examination unfolds concerning the attributes of magnetohydrodynamic (MHD) boundary layer flow and heat transfer inherent to nanoliquids derived from Sisko Al2 O3-Eg and TiO2-Eg compositions. Such nanoliquids are subjected to an extending surface. Consideration is duly given to slip boundary conditions, as well as the effects stemming from variable viscosity and variable thermal conductivity. The analytical approach applied involves the application of suitable similarity transformations. These conversions serve to transform the initial set of complex nonlinear partial differential equations into a more manageable assembly of ordinary differential equations. Through the utilization of the FEM, these reformulated equations are solved, considering the specified boundary conditions. The outcomes attained are graphically depicted by means of plots and tables. These visual aids facilitate a comprehensive exploration of how diverse parameters exert influence over the distributions of velocity, temperature, and concentration. Furthermore, detailed scrutiny is directed towards the fluctuations characterizing pivotal parameters, viz., Nusselt number, skin-friction coefficient, and Sherwood number. It is identified that the Nusselt number showcases a diminishing trend coinciding with increasing values of the volume fraction parameter (φ). This trend remains consistent regardless of whether the nanoliquid under consideration is Al2O3-Eg or TiO2-Eg based. In contrast, both the skin-friction coefficient and Sherwood number assume lower values as the volume fraction parameter (φ) escalates. This pattern remains congruent across both classifications of nanoliquids. The findings of the study impart valuable insights into the complex interplay governing the characteristics of HMT pertaining to Sisko Al2 O3-Eg and TiO2-Eg nanoliquids along an extending surface. © 2024, Tech Science Press. All rights reserved.
format Article
author Jyothi, K.
Dasore, Abhishek
Ganapati, R.
Shareef, Sk. Mohammad
Chamkha, Ali J.
Prasad, V. Raghavendra
spellingShingle Jyothi, K.
Dasore, Abhishek
Ganapati, R.
Shareef, Sk. Mohammad
Chamkha, Ali J.
Prasad, V. Raghavendra
Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface
author_facet Jyothi, K.
Dasore, Abhishek
Ganapati, R.
Shareef, Sk. Mohammad
Chamkha, Ali J.
Prasad, V. Raghavendra
author_sort Jyothi, K.
title Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface
title_short Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface
title_full Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface
title_fullStr Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface
title_full_unstemmed Comparative numerical analysis of heat and mass transfer characteristics in Sisko Al2O3-EG and TiO2-EG fluids on a stretched surface
title_sort comparative numerical analysis of heat and mass transfer characteristics in sisko al2o3-eg and tio2-eg fluids on a stretched surface
publisher Tech Science Press
publishDate 2024
url http://psasir.upm.edu.my/id/eprint/112035/1/112035.pdf
http://psasir.upm.edu.my/id/eprint/112035/
https://doi.org/10.32604/fhmt.2024.046891
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