Impact of non-linear heat source and magnetic field on the Carreau nanofluid Marangoni convective flow - a numerical investigation

被引:8
作者
Alhushaybari, Abdullah [1 ]
Hussain, Syed M. [2 ]
E. E. Abulhassan, Mawadda [3 ]
Alharthi, Aiedh Mrisi [1 ]
Ali, Kashif [4 ]
Ahmad, Sohail [4 ]
Jamshed, Wasim [5 ,6 ,7 ]
机构
[1] Taif Univ, Turabah Univ Coll, Taif, Saudi Arabia
[2] Islamic Univ Madinah, Fac Sci, Dept Math, Madinah, Saudi Arabia
[3] King Khalid Univ, Coll Sci, Dept Math, Abha, Saudi Arabia
[4] Muhammad Nawaz Sharif Univ Engn & Technol, Dept Basic Sci & Humanities, Multan, Pakistan
[5] Capital Univ Sci & Technol CUST, Dept Math, Islamabad, Pakistan
[6] Al Ayen Univ, Sci Res Ctr, Math Appl Sci & Engn Res Grp, Nasiriyah, Iraq
[7] Capital Univ Sci & Technol CUST, Dept Math, Islamabad, Pakistan
关键词
Nonlinear heat source; Carreau nanofluids; thermal radiation; dusty mixed convection; Marangoni convection; MASS-TRANSFER; FLUID;
D O I
10.1080/02286203.2024.2320612
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
A recent study examines the features of a dusty Carreau nanofluid over a flat surface with allowance for mixed convection that is not linear and heat radiation. It also examines how these factors affect fluid movement due to temperature differences (thermal Marangoni effect). The change in surface tension levels causes Marangoni convection, which finds applications in scientific areas like making crystals, keeping soap bubbles steady, drying thin wafers and dry silicon. Similarity transformations have been incorporated to create ODEs from PDEs. The complex non-dimensional differential equations are then solved using a numerical method called shooting method (with RKF-45 approach). For the momentum and heat distribution analysis, physical parameters are expressed in detail. The findings show that the Marangoni flow makes heat move quicker. In the same way, there is a decrease in the fluid's velocity due to magnetic effects.
引用
收藏
页数:15
相关论文
共 26 条
[1]   Numerically analysis of Marangoni convective flow of hybrid nanofluid over an infinite disk with thermophoresis particle deposition [J].
Abbas, Munawar ;
Khan, Nargis ;
Hashmi, M. S. ;
Younis, Jihad .
SCIENTIFIC REPORTS, 2023, 13 (01)
[2]   Novel thermal aspects of hybrid nanoparticles Cu-TiO2 in the flow of ethylene glycol [J].
Ahmad, Sohail ;
Ali, Kashif ;
Faridi, Aftab Ahmed ;
Ashraf, Muhammad .
INTERNATIONAL COMMUNICATIONS IN HEAT AND MASS TRANSFER, 2021, 129
[3]   MHD stagnation point flow of Carreau fluid toward a permeable shrinking sheet: Dual solutions [J].
Akbar, N. S. ;
Nadeem, S. ;
Ul Haq, Rizwan ;
Ye, Shiwei .
AIN SHAMS ENGINEERING JOURNAL, 2014, 5 (04) :1233-1239
[4]   Numerical simulation of peristaltic flow of a Carreau nanofluid in an asymmetric channel [J].
Akbar, Noreen Sher ;
Nadeem, S. ;
Khan, Zafar Hayat .
ALEXANDRIA ENGINEERING JOURNAL, 2014, 53 (01) :191-197
[5]   Simulation analysis of MHD hybrid Cu-Al2O3/H2O nanofluid flow with heat generation through a porous media [J].
Ali, Kashif ;
Ahmad, Sohail ;
Nisar, Kottakkaran Sooppy ;
Faridi, Aftab Ahmed ;
Ashraf, Muhammad .
INTERNATIONAL JOURNAL OF ENERGY RESEARCH, 2021, 45 (13) :19165-19179
[6]   Peristaltic motion of a Carreau fluid in an asymmetric channel [J].
Ali, Nasir ;
Hayat, Tasawar .
APPLIED MATHEMATICS AND COMPUTATION, 2007, 193 (02) :535-552
[7]   Three-Dimensional Swirling Flow of Nanofluid with Nanoparticle Aggregation Kinematics Using Modified Krieger-Dougherty and Maxwell-Bruggeman Models: A Finite Element Solution [J].
Alsulami, M. D. ;
Abdulrahman, Amal ;
Kumar, R. Naveen ;
Gowda, R. J. Punith ;
Prasannakumara, B. C. .
MATHEMATICS, 2023, 11 (09)
[8]   Magnetohydrodynamic Flow of a Bingham Fluid in a Vertical Channel: Mixed Convection [J].
Borrelli, Alessandra ;
Giantesio, Giulia ;
Patria, Maria Cristina .
FLUIDS, 2021, 6 (04)
[9]   Entropy analysis in the Rabinowitsch fluid model through inclined Wavy Channel: Constant and variable properties [J].
Chu, Yu-Ming ;
Nazeer, Mubbashar ;
Khan, M. Ijaz ;
Ali, Waqas ;
Zafar, Zareen ;
Kadry, Seifedine ;
Abdelmalek, Zahra .
INTERNATIONAL COMMUNICATIONS IN HEAT AND MASS TRANSFER, 2020, 119
[10]   Analysis of the Magnetohydrodynamic Behavior of the Fully Developed Flow of Conducting Fluid [J].
Fonseca, Wellington da Silva ;
Araujo, Ramon C. F. ;
Silva, Marcelo de Oliveira e ;
Cruz, Daniel Onofre de A. .
ENERGIES, 2021, 14 (09)