期刊
MATHEMATICS
卷 10, 期 10, 页码 -出版社
MDPI
DOI: 10.3390/math10101658
关键词
hybrid ferrofluid; magnetohydrodynamics; rotating disk; stability analysis; unsteady flow
类别
资金
- MOHE Malaysia
- Universiti Teknikal Malaysia Melaka [JURNAL/2019/FTKMP/Q00042, FRGS/1/2021/STG06/UTEM/03/1]
This study discusses the impact of unsteady magnetohydrodynamics hybrid ferrofluid flow over a stretching/shrinking rotating disc. By transforming the mathematical model into ordinary differential equations and analyzing the solutions, it is found that both solutions are stable. The research also reveals that the unsteadiness parameter decreases the boundary layer thickness of velocity and temperature distribution, while the magnetic and mass flux parameters have a lowering effect on the skin friction coefficient and the unsteadiness parameter has a supportive effect on the heat transfer rate.
The flow of fluids over the boundaries of a rotating disc has many practical uses, including boundary-layer control and separation. Therefore, the aim of this study is to discuss the impact of unsteady magnetohydrodynamics (MHD) hybrid ferrofluid flow over a stretching/shrinking rotating disk. The time-dependent mathematical model is transformed into a set of ordinary differential equations (ODE's) by using similarity variables. The bvp4c method in the MATLAB platform is utilised in order to solve the present model. Since the occurrence of more than one solution is presentable, an analysis of solution stabilities is conducted. Both solutions were surprisingly found to be stable. Meanwhile, the skin friction coefficient, heat transfer rate-in cooperation with velocity-and temperature profile distributions are examined for the progressing parameters. The findings reveal that the unsteadiness parameter causes the boundary layer thickness of the velocity and temperature distribution profile to decrease. A higher value of magnetic and mass flux parameter lowers the skin friction coefficient. In contrast, the addition of the unsteadiness parameter yields a supportive effect on the heat transfer rate. An increment of the magnetic parameter up to 30% reduces the skin friction coefficient by 15.98% and enhances the heat transfer rate approximately up to 1.88%, significantly. In contrast, the heat transfer is rapidly enhanced by improving the mass flux parameter by almost 20%.
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