Stability analysis of buoyancy magneto flow of hybrid nanofluid through a stretchable/shrinkable vertical sheet induced by a micropolar fluid subject to nonlinear heat sink/source

Khan, Umair and Ishak, Anuar and Zaib, Aurang and Abeer M. Alotaibi and Sayed M. Eldin and Akkurt, Nevzat and Waini, Iskandar and Madhukesh, Javali Kotresh (2022) Stability analysis of buoyancy magneto flow of hybrid nanofluid through a stretchable/shrinkable vertical sheet induced by a micropolar fluid subject to nonlinear heat sink/source. Magnetochemistry, 8 (12). 01-28. ISSN 2312-7481

Text KHAN2022 MAGNETOCHEMISTRY-08-00188-V2.PDF Download (9MB)

Abstract

The utilization of hybrid nanofluids (HNs) to boost heat transfer is a promising area of study, and thus, numerous scientists, researchers, and academics have voiced their admiration and interest in this area. One of the main functions of nanofluids is their dynamic role in cooling small electrical devices such as microchips and associated gadgets. The major goal of this study is to perform an analysis of the buoyancy flow of a shrinking/stretching sheet, whilst considering the fascinating and practical uses of hybrid nanofluids. The influence of a nonlinear heat source/sink induced by a micropolar fluid is also inspected. Water-based alumina and copper nanoparticles are utilized to calculate the fine points of the fluid flow and the features of heat transfer. The governing equations are framed with acceptable assumptions and the required similarity transformations are used to turn the set of partial differential equations into ordinary differential equations. The bvp4c technique is used to solve the simplified equations. Dual solutions are presented for certain values of stretching/shrinking parameters as well as the mixed convective parameter. In addition, the shear stress coefficient in the first-branch solution (FBS) escalates and decelerates for the second-branch solution (SBS) with the superior impact of the magnetic parameter, the mass transpiration parameter, and the solid nanoparticles volume fraction, while the contrary behavior is seen in both (FB and SB) solutions for the larger values of the material parameter.

Item Type:	Article
Uncontrolled Keywords:	Hybrid nanofluid, Micropolar fluid, Nonlinear heat source/sink
Divisions:	Faculty of Mechanical and Manufacturing Engineering Technology
Depositing User:	Sabariah Ismail
Date Deposited:	02 Mar 2023 16:28
Last Modified:	02 Mar 2023 16:28
URI:	http://eprints.utem.edu.my/id/eprint/26274
Statistic Details:	View Download Statistic

Actions (login required)

View Item