Your search keyword '"Hassan, Ali"' showing total 8 results

1. Rotating Hybrid Nanofluid Flow with Chemical Reaction and Thermal Radiation between Parallel Plates.

Author

Arshad, Mubashar, Hassan, Ali, Haider, Qusain, Alharbi, Fahad M., Alsubaie, Najah, Alhushaybari, Abdullah, Burduhos-Nergis, Diana-Petronela, and Galal, Ahmed M.

Subjects

*HEAT radiation & absorption, *CHEMICAL reactions, *NANOFLUIDS, *PARTIAL differential equations, *BOUNDARY value problems, *ROTATING fluid

Abstract

This research investigates the two different hybrid nanofluid flows between two parallel plates placed at two different heights, y 0   and y h , respectively. Water-based hybrid nanofluids are obtained by using A l 2 O 3 , T i O 2 and C u as nanoparticles, respectively. The upper-level plate is fixed, while the lower-level plate is stretchable. The fluid rotates along the y-axis. The governing equations of momentum, energy and concentration are transformed into partial differential equations by using similarity transformations. These transformed equations are grasped numerically at MATLAB by using the boundary value problem technique. The influence of different parameters are presented through graphs. The numerical outcomes for rotation, Nusselt, Prandtl, and Schmidt numbers are obtained in the form of tables. The heat transfer rate increases by augmentation in the thermophoresis parameter, while it decays by increasing the Reynolds number. Oxide nanoparticles hybrid nanofluid proved more efficient as compared to mixed nanoparticles hybrid nanofluid. This research suggests using oxide nanoparticles for good heat transfer. [ABSTRACT FROM AUTHOR]

Published

2022

2. Heat and Mass Transport Analysis of MHD Rotating Hybrid Nanofluids Conveying Silver and Molybdenum Di-Sulfide Nano-Particles under Effect of Linear and Non-Linear Radiation.

Author

Hassan, Ali, Hussain, Azad, Arshad, Mubashar, Awrejcewicz, Jan, Pawlowski, Witold, Alharbi, Fahad M., and Karamti, Hanen

Subjects

*HEAT transfer coefficient, *NANOPARTICLES, *RADIATION, *NANOFLUIDS, *NONLINEAR differential equations, *PARTIAL differential equations, *NANOSATELLITES

Abstract

This article is an attempt to explore the heat transfer features of the steady three-dimensional rotating flow of magneto-hydrodynamic hybrid nanofluids under the effect of nonlinear radiation over the bi-directional stretching surface. For this purpose, two different nano-particles, namely silver (Ag) and molybdenum di-sulfide (MoS2), were selected. Three different conventional base fluids were utilized to form desired hybrid nanofluids such as water (H2O), engine oil (EO), and ethylene glycol (EG). We obtained steady three-dimensional highly nonlinear partial differential equations. These highly nonlinear partial differential equations cannot be solved analytically, so these equations were handled in MATLAB with the BVP-4C technique with convergence tolerance at 10−6. The graph depicts the effect of the magnetization effect, thermal radiation, and stretching ratio on rotating hybrid nanofluids. Additionally, the impact of thermal radiation on the heat coefficient of three different hybrid nanofluids is being investigated. The augmentation in magnetization decreases the primary velocity, whereas the increment in radiation enhances the primary velocity. The stretching ratio and the presence of higher magnetic forces increase the temperature profile. The concentration profile was enhanced with an increment in the magnetic field, stretching, and rotation ratio. The maximum Nusselt number was achieved for the Ag-MoS2/EO hybrid nanofluid. It was concluded that augmentation in nonlinear radiation enhances the heat transfer coefficient for the examined cases (I) and (II) of the hybrid nanofluids. The Nusselt number doubled for both the examined cases under nonlinear radiation. Moreover, it was discovered that Ag-MoS2/water produced the best heat transfer results under nonlinear radiation. Therefore, the study recommends more frequent exploration of hybrid nanofluids (Ag-MoS2/water) when employing nonlinear radiation to analyze the heat transfer coefficient. [ABSTRACT FROM AUTHOR]

Published

2022

3. Numerical and Thermal Investigation of Magneto-Hydrodynamic Hybrid Nanoparticles (SWCNT-Ag) under Rosseland Radiation: A Prescribed Wall Temperature Case.

Author

Hassan, Ali, Hussain, Azad, Arshad, Mubashar, Alanazi, Meznah M., and Zahran, Heba Y.

Subjects

*ORDINARY differential equations, *MASS transfer coefficients, *NONLINEAR differential equations, *BOUNDARY value problems, *ROTATIONAL flow, *PARTIAL differential equations, *MASS transfer, *NANOFLUIDS

Abstract

Thermal heat generation and enhancement have been examined extensively over the past two decades, and nanofluid technology has been explored to address this issue. In the present study, we discuss the thermal heat coefficient under the influence of a rotating magneto-hydrodynamic hybrid nanofluid over an axially spinning cone for a prescribed wall temperature (PWT) case. The governing equations of the formulated problem are derived by utilizing the Rivlin–Ericksen tensor and boundary layer approximation (BLA). We introduce our suppositions to transform the highly non-linear partial differential equations into ordinary differential equations. The numerical outcomes of the problem are drafted in MATLAB with the of help the boundary value problem algorithm. The influences of several study parameters are obtained to demonstrate and analyze the magneto-hydrodynamic flow characteristics. The heat and mass transfer coefficients increase and high Nusselt and Sherwood numbers are obtained with reduced skin coefficients for the analyzed composite nanoparticles. The analyzed hybrid nanofluid (SWCNT-Ag–kerosene oil) produces reduced drag and lift coefficients and high thermal heat rates when compared with a recent study for SWCNT-MWCNT–kerosene oil hybrid nanofluid. Maximum Nusselt (Nu) and Sherwood (Sh) numbers are observed under a high rotational flow ratio and pressure gradient. Based on the results of this study, we recommend more frequent use of the examined hybrid nanofluid. [ABSTRACT FROM AUTHOR]

Published

2022

4. Numerical appraisal of Yamada–Ota hybrid nanofluid flow over a cylindrical surface and a sheet with surface-catalyzed reaction using Keller box approximations.

Author

Ramzan, Muhammad, Gul, Hina, Ghazwani, Hassan Ali S., Nisar, Kottakkaran Sooppy, and Saleel, C. Ahamed

Subjects

*NANOFLUIDS, *BOUNDARY layer equations, *ORDINARY differential equations, *PARTIAL differential equations, *HEAT radiation & absorption, *FLUID-structure interaction, *HYBRID systems

Abstract

Hybrid nanofluids (HNF) are the advanced form of nanofluids used for improved heat transfer purposes. Taking this point in mind, the objective of the presented endeavor is to examine the Yamada–Ota HNF flow model comprising (gold–silver/engine oil) over a stretched cylindrical surface and a sheet (as a limiting case) in a permeable medium. The novelty of this research is the consideration of the surface-catalyzed reaction along with the homogeneous–heterogeneous reactions to accelerate the chemical reactions in the shortest possible time. The heat transport phenomenon is strengthened with the support of Joule heating, heat absorption/generation, and the convective heat boundary condition at the surface of the cylinder. The obtained ordinary differential equations are reduced from the partial differential equations using boundary layer theory and are numerically computed using the Keller box method. It is witnessed that for varied estimates of the magnetic parameter, the thermal profile enhances while the velocity field reduces. It is also noted that the fluid concentration is reduced when the surface-catalyzed parameter is enhanced. The validation of the envisioned model in a limiting case is also added to this investigation. [ABSTRACT FROM AUTHOR]

Published

2023

5. Stability analysis of GO‐EG and GO‐blood base nanofluids by implementing of thermal radiation phenomena.

Author

Rehman, Ali, Zeb, Muhammad, Khun, Ma Chau, Imran, Ali, Ahmad, Sohail, and Ghazwani, Hassan Ali

Subjects

*HEAT radiation & absorption, *BOUNDARY layer equations, *THERMAL boundary layer, *NONLINEAR differential equations, *PARTIAL differential equations, *THERMAL conductivity, *NANOFLUIDS

Abstract

This work leaves to explore the stability of a 2‐D, time free, thermal boundary layer of graphene oxide ethylene glycol (GO‐EG,) where GO‐blood is taken as base nanofluids over a stretchable surface by executing a magnetic field (MHD), coupled stress effects, heat source/sink, and sun‐oriented radiations. This work is done due to the reason that nanofluids have a higher heat conductivity level rather than regular liquids. Nonlinear partial differential equations (N‐PDEs) are modeled utilizing the notable boundary layer equations. Dimensionless ordinary differential conditions (ODEs) are made from the created NPDEs by utilizing dimensional analysis and group theoretic approach. We examine the obtained ODEs through the notable homotopy analysis technique (HAM). The impacts of different parameters on temperature distribution and velocity profiles are shown graphically. However, some tables are constructed in support of the presented study to confirm the stability and convergence of the solutions. The main intentions in this work are to underline the enhancement of traditional heat transfer's thermal conductivity. [ABSTRACT FROM AUTHOR]

Published

2024

6. Comparative appraisal of mono and hybrid nanofluid flows comprising carbon nanotubes over a three-dimensional surface impacted by Cattaneo–Christov heat flux.

Author

Alharbi, Khalid Abdulkhaliq M., Ramzan, Muhammad, Shahmir, Nazia, Ghazwani, Hassan Ali S., Elmasry, Yasser, Eldin, Sayed M., and Bilal, Muhammad

Subjects

*HEAT flux, *NANOFLUIDS, *CARBON nanotubes, *COMPOSITE materials, *ETHYLENE glycol, *PARTIAL differential equations, *HEAT transfer

Abstract

Carbon nanotubes (CNTs) are nanoscale tubes made of carbon atoms with unique mechanical, electrical, and thermal properties. They have a variety of promising applications in electronics, energy storage, and composite materials and are found as single-wall carbon nanotubes (SWCNTs) and double-wall carbon nanotubes (DWCNTs). Considering such alluring attributes of nanotubes, the motive of the presented flow model is to compare the thermal performance of magnetohydrodynamic (MHD) mono (SWCNTs)/Ethylene glycol) and hybrid (DWCNTs- SWCNTs/Ethylene glycol) nanofluids over a bidirectional stretching surface. The thermal efficiency of the proposed model is gauged while considering the effects of Cattaneo-Christov heat flux with prescribed heat flux (PHF) and prescribed surface temperature (PST). The flow is assisted by the anisotropic slip at the boundary of the surface. The system of partial differential equations (PDEs) is converted into a nonlinear ordinary differential system by the use of similarity transformations and handled using the bvp4c numerical technique. To depict the relationship between the profiles and the parameters, graphs, and tables are illustrated. The significant outcome revealed that the fluid temperature rises in the scenario of both PST and PHF cases. In addition, the heat transfer efficiency of the hybrid nanoliquid is far ahead of the nanofluid flow. The truthfulness of the envisioned model in the limiting scenario is also given. [ABSTRACT FROM AUTHOR]

Published

2023

7. Performance-based comparison of Yamada–Ota and Hamilton–Crosser hybrid nanofluid flow models with magnetic dipole impact past a stretched surface.

Author

Gul, Hina, Ramzan, Muhammad, Nisar, Kottakkaran Sooppy, Mohamed, Roshan Noor, and Ghazwani, Hassan Ali S.

Subjects

*MAGNETIC dipoles, *NANOFLUIDS, *NANOFLUIDICS, *ORDINARY differential equations, *PARTIAL differential equations, *SILICON carbide, *SIMILARITY transformations

Abstract

The nanofluid flows play a vital role in many engineering processes owing to their notable industrial usage and excessive heat transfer abilities. Lately, an advanced form of nanofluids namely "hybrid nanofluids" has swapped the usual nanofluid flows to further augment the heat transfer capabilities. The objective of this envisaged model is to compare the performance of two renowned hybrid nanofluid models namely Hamilton–Crosser and Yamada–Ota. The hybrid nanoliquid (TiO2-SiC/DO) flow model is comprised of Titanium oxide (TiO2) and Silicon carbide (SiC) nanoparticles submerged into Diathermic oil (DO). The subject flow is considered over a stretched surface and is influenced by the magnetic dipole. The uniqueness of the fluid model is augmented by considering the modified Fourier law instead of the traditional Fourier law and slip conditions at the boundary. By applying the suitable similarity transformations, the system of ordinary differential equations obtained from the leading partial differential equations is handled by the MATLAB solver bvp4c package to determine the numerical solution. It is divulged that the Yamada–Ota model performs considerably better than the Hamilton–Crosser flow model as far as heat transfer capabilities are concerned. Further, the velocity reduces on increasing hydrodynamic interaction and slip parameters. It is also noted that both temperature profiles increase for higher hydrodynamic interaction and viscous dissipation parameters. The envisioned model is authenticated when compared with an already published result in a limiting case. [ABSTRACT FROM AUTHOR]

Published

2022

8. Three-Dimensional Water-Based Magneto-Hydrodynamic Rotating Nanofluid Flow over a Linear Extending Sheet and Heat Transport Analysis: A Numerical Approach.

Author

Hussain, Azad, Arshad, Mubashar, Rehman, Aysha, Hassan, Ali, Elagan, S. K., Ahmad, Hijaz, and Ishan, Amira

Subjects

*NANOFLUIDS, *NANOFLUIDICS, *NUMERICAL analysis, *ORDINARY differential equations, *PARTIAL differential equations, *DIFFERENTIAL equations

Abstract

This comparative study inspects the heat transfer characteristics of magnetohydrodynamic (MHD) nanofluid flow. The model employed is a two-phase fluid flow model. Water is utilized as the base fluid, and zinc and titanium oxide ( Zn and TiO 2 ) are used as two different types of nanoparticles. The rotation of nanofluid is considered along the z-axis, with velocity   ω * . A similarity transformation is used to transform the leading structure of partial differential equations to ordinary differential equations. By using a powerful mathematical BVP-4C technique, numerical results are obtained. This study aims to describe the possessions of different constraints on temperature and velocity for rotating nanofluid with a magnetic effect. The outcomes for the rotating nanofluid flow and heat transference properties for both types of nanoparticles are highlighted with the help of graphs and tables. The impact of physical concentrations such as heat transference rates and coefficients of skin friction are examined. It is noted that rotation increases the heat flux and decreases skin friction. In this comparative study, Zn -water nanofluid was demonstrated to be a worthy heat transporter as compared to TiO 2 -water nanofluid. [ABSTRACT FROM AUTHOR]

Published

2021