Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity

The main goal of this research is to present the concept of enhancing heat transfer within emerging technology. To achieve this, tiny metal and nonmetal particles ranging from 1 to 100 nm in size are introduced into base liquids. These nanoscale particles are utilized to improve the thermal performa...

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Main Authors: Rehman A., Khun M.C., Salleh Z., Khan W., Albely M.S., Jan R., Alhabeeb S.A.
Other Authors: 57210205189
Format: Article
Published: Elsevier Ltd 2024
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spelling my.uniten.dspace-338652024-10-14T11:17:21Z Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity Rehman A. Khun M.C. Salleh Z. Khan W. Albely M.S. Jan R. Alhabeeb S.A. 57210205189 56257963400 57195479070 57192098132 58762134400 57205596279 58688129400 Couple stress parameter GO-EG GO-W HAM BVP2.0 package Nanofluidics Nanomaterial Stretching cylinder The main goal of this research is to present the concept of enhancing heat transfer within emerging technology. To achieve this, tiny metal and nonmetal particles ranging from 1 to 100 nm in size are introduced into base liquids. These nanoscale particles are utilized to improve the thermal performance of the liquids, leading to what are termed nanofluids. The utilization of these fluids and the examination of the flow of thin films have valuable implications across various sectors such as engineering, technology, and industries. This research focuses on analyzing the convective flow behavior of nanofluids, specifically, graphene oxide-ethylene glycol (GO?EG) and graphene oxide-water (GO?W) on a moving surface. The study investigates the impacts of magnetic fields and varying viscosity. By making use of the thermophysical characteristics of the base fluid and the nanofluid, as well as implementing a similarity transformation within the fundamental equations that govern energy and momentum, we formulate a 5th order nonlinear ordinary differential equation (NODE) to describe the velocity profile. This is combined with a second-order NODE that describes the distribution of temperature. To solve this derived NODE, we employ a method known as the Homotopy Analysis Method (HAM) for analytical solution. The impact of the relevant factors, Prandtl number, including magnetic field parameter, thickness of the liquid, couple stress parameter, temperature distribution, dynamic viscosity, and Eckert number, on the skin friction, velocity profile, and Nusselt's number are interrogated through graphical representation. The velocity field exhibits a decline as the couple stress parameter, magnetic field parameter, liquid thickness, and dynamic viscosity experience an increase. Conversely, the temperature field displays a rise as the Eckert number and dynamic viscosity experience an increase. To ensure the convergence of the issue, dual solutions of the problem are employed, and this is verified through the utilization graphs and tables. Due to the considerable challenge encountered in heat transfer applications for cooling diverse equipment and devices across industries like automotive, microelectronics, defense, and manufacturing, there is a strong expectation that this theoretical methodology could make a favorable contribution towards enhancing heat transfer efficiency. This improvement is sought to meet the requirements of the manufacturing and engineering sectors. � 2023 Final 2024-10-14T03:17:21Z 2024-10-14T03:17:21Z 2023 Article 10.1016/j.heliyon.2023.e22491 2-s2.0-85179735731 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85179735731&doi=10.1016%2fj.heliyon.2023.e22491&partnerID=40&md5=7cd06117e5aa64068c60f09d7c69d3ee https://irepository.uniten.edu.my/handle/123456789/33865 9 12 e22491 All Open Access Gold Open Access Elsevier Ltd Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Couple stress parameter
GO-EG
GO-W
HAM BVP2.0 package
Nanofluidics
Nanomaterial
Stretching cylinder
spellingShingle Couple stress parameter
GO-EG
GO-W
HAM BVP2.0 package
Nanofluidics
Nanomaterial
Stretching cylinder
Rehman A.
Khun M.C.
Salleh Z.
Khan W.
Albely M.S.
Jan R.
Alhabeeb S.A.
Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity
description The main goal of this research is to present the concept of enhancing heat transfer within emerging technology. To achieve this, tiny metal and nonmetal particles ranging from 1 to 100 nm in size are introduced into base liquids. These nanoscale particles are utilized to improve the thermal performance of the liquids, leading to what are termed nanofluids. The utilization of these fluids and the examination of the flow of thin films have valuable implications across various sectors such as engineering, technology, and industries. This research focuses on analyzing the convective flow behavior of nanofluids, specifically, graphene oxide-ethylene glycol (GO?EG) and graphene oxide-water (GO?W) on a moving surface. The study investigates the impacts of magnetic fields and varying viscosity. By making use of the thermophysical characteristics of the base fluid and the nanofluid, as well as implementing a similarity transformation within the fundamental equations that govern energy and momentum, we formulate a 5th order nonlinear ordinary differential equation (NODE) to describe the velocity profile. This is combined with a second-order NODE that describes the distribution of temperature. To solve this derived NODE, we employ a method known as the Homotopy Analysis Method (HAM) for analytical solution. The impact of the relevant factors, Prandtl number, including magnetic field parameter, thickness of the liquid, couple stress parameter, temperature distribution, dynamic viscosity, and Eckert number, on the skin friction, velocity profile, and Nusselt's number are interrogated through graphical representation. The velocity field exhibits a decline as the couple stress parameter, magnetic field parameter, liquid thickness, and dynamic viscosity experience an increase. Conversely, the temperature field displays a rise as the Eckert number and dynamic viscosity experience an increase. To ensure the convergence of the issue, dual solutions of the problem are employed, and this is verified through the utilization graphs and tables. Due to the considerable challenge encountered in heat transfer applications for cooling diverse equipment and devices across industries like automotive, microelectronics, defense, and manufacturing, there is a strong expectation that this theoretical methodology could make a favorable contribution towards enhancing heat transfer efficiency. This improvement is sought to meet the requirements of the manufacturing and engineering sectors. � 2023
author2 57210205189
author_facet 57210205189
Rehman A.
Khun M.C.
Salleh Z.
Khan W.
Albely M.S.
Jan R.
Alhabeeb S.A.
format Article
author Rehman A.
Khun M.C.
Salleh Z.
Khan W.
Albely M.S.
Jan R.
Alhabeeb S.A.
author_sort Rehman A.
title Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity
title_short Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity
title_full Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity
title_fullStr Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity
title_full_unstemmed Analytical study on couple stress flow of GO-EG and GO-W nanofluid over an extending cylinder along with variable viscosity
title_sort analytical study on couple stress flow of go-eg and go-w nanofluid over an extending cylinder along with variable viscosity
publisher Elsevier Ltd
publishDate 2024
_version_ 1814061091289825280
score 13.214268