Impact of viscous dissipation and coriolis effects in heat and mass transfer analysis of the 3D non-Newtonian fluid flow

Alharbi, Khalid Abdulkhaliq M.; Ullah, Asad; Ikramullah, Ikramullah; Fatima, Nahid; Khan, Rajwali; Sohail, Mohammad; Khan, Shahid Ali; Khan, Waris; Ali, Fawad

doi:10.1016/j.csite.2022.102289

Cited by 23 publications

(11 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Ferdows et al [12] analyzed the thermal cooling performance of a convective nanofuid fowing across a moving extending surface. Alharbi et al [13] investigated the efects of viscous dissipation and Coriolis on the heat and mass transfer of a 3D nonNewtonian fuid fow. Ali et al [14] numerically simulated a bioconvective fow of a nanofuid over a stretching and heating surface.…”

Section: Introductionmentioning

confidence: 99%

Effects of Thermal Radiation and Chemical Reaction on Hydromagnetic Fluid Flow in a Cylindrical Collapsible Tube with an Obstacle

Mwamba¹,

Abonyo

Awuor

2023

International Journal of Mathematics and Mathematical Sciences

View full text Add to dashboard Cite

The aim of this research is to study the effects of thermal radiation and chemical reaction on hydromagnetic fluid flow in a cylindrical collapsible tube with an obstacle. The fluid flow is governed by continuity, momentum, energy, and concentration equations. Similarity transformation has been used to convert the obtained PDEs into ODEs. The collocation method has been used to numerically solve the ODEs. The method has been implemented in MATLAB using the bvp4c inbuilt function. The effects of the nondimensional parameters on velocity, temperature, and concentration have been presented graphically. Additionally, the skin-friction coefficient, the Nusselt number, and the Sherwood number have been discussed and are presented in a tabular form. The findings demonstrated that increasing the Reynolds number causes a rise in the fluid temperature and velocity. The fluid velocity decreases as the Hartmann number and the weight of the obstacle increase but increases with increasing Grashof numbers. The temperature of the fluid increases as the radiation parameter, or Eckert number, increases, but decreases as the Prandtl number increases. As the Soret number rises, so do the fluid’s temperature and concentration distribution. With an increase in the unsteadiness parameter, the fluid velocity and the concentration distribution decrease, whereas the opposite is seen in temperature. As the Schmidt number, the concentration Grashof number, and the chemical reaction parameter increase, the fluid’s concentration decreases. There is an increase in skin-friction coefficient with increasing Prandtl number, Eckert number, Soret number, thermal Grashof number, concentration Grashof number, thermal radiation parameter, Hartmann number, and unsteadiness parameter, while a decrease is observed with increasing Reynolds number. The Nusselt number increases with an increase in the Prandtl number, Eckert number, thermal radiation parameter, Hartmann number, and unsteadiness parameter. A slight decrease in the Nusselt number has been observed with increasing thermal Grashof number. The Sherwood number decreases with increasing Prandtl number, chemical reaction parameter, and thermal radiation parameter but increases with increasing Schmidt number, Eckert number, and Soret number. The research has the potential for a wide range of applications including but not limited to the medical field and other physical sciences.

show abstract

Section: Introductionmentioning

confidence: 99%

Effects of Thermal Radiation and Chemical Reaction on Hydromagnetic Fluid Flow in a Cylindrical Collapsible Tube with an Obstacle

Mwamba¹,

Abonyo

Awuor

2023

International Journal of Mathematics and Mathematical Sciences

View full text Add to dashboard Cite

show abstract

“…The increasing rotation parameter augments the horizontal component of velocity and reduces the velocity vertical component. The fluid temperature enhances with the increasing strength of radiation source, internal heat source, and reflection parameters [7].…”

Section: Literature Reviewmentioning

confidence: 99%

Effect of Viscous Dissipation (<i>Φ</i>) on Temperature Distribution of Blood Plasma in Presence of a Magnetic Field

Moseti,

Kerongo,

Bulinda

2023

View full text Add to dashboard Cite

Applications of heat transfer show the variations in temperature of the body which is helpful for the purpose of thermal therapy in the treatment of tumor glands. This study considered theoretical approaches in analyzing the effect of viscous dissipation on temperature distribution on the flow of blood plasma through an asymmetric arterial segment. The plasma was considered to be unsteady, laminar and an incompressible fluid through non-uniform arterial segment in a two-dimensional flow. Numerical schemes developed for the coupled partial differential equations governing blood plasma were solved using Finite Difference scheme (FDS). With the aid of the finite difference approach and the related boundary conditions, results for temperature profiles were obtained. The study determined the effect of viscous dissipation on temperature of blood plasma in arteries. The equations were solved using MATLAB softwares and results were presented graphically and in tables. The increase in viscous dissipation tends to decrease blood plasma heat distribution. This study will find important application in hospitals.

show abstract

“…Majeed et al [18] concluded the results of viscous dissipation on the MHD fluid flowing on the exponential porous surface. Alharbi et al [19] examined the transmission of heat with viscous dissipation in terms of 3D Carreau fluid motion on the parabolic surface. Kudenatti et al [20] conducted a numerical study based on the boundary layer flow of non-Newtonian fluid which is moving on a wedge in the existence of viscous dissipation.…”

Section: Introductionmentioning

confidence: 99%

Stagnation point flow of MHD non-Newtonian fluid and thermal investigation with Joule heating, viscous dissipation and Soret effect

Awais,

Salahuddin

2024

Preprint

View full text Add to dashboard Cite

The aim of this study is to analyze the numerical solution of magnetohydrodynamic Jeffery fluid past over the upper horizontal parabolic surface with the help of Adam-Milne Predictor Corrector method along with the RK method. Adams predictor-corrector technique is very significant because it improve accuracy of results as compared to using either method alone. The predictor step gives an initial approximation and the corrector step refines this approximation based on the implicit equation. The assumption based on the boundary layer and stagnation point flow of magnetohydrodynamic Jeffery fluid which is past on the melting upper horizontal parabolic surface and the physical aspects are examined with the variable fluid properties. The velocity slip effect on the surface of paraboloid is used to determine its influence on the movement of fluid. The thermal and solutal transfer rates has crucial role in the chemical reactions, climate changes, electronic devices, distillation and separation processes, water and air pollution. Therefore we considered both the thermal and solutal transfer rates with the effects of Joule heating, viscous dissipation, heat source/sink, activation energy and Soret effect. The implementation of all the assumption on the basic conservation laws gives us the governing equation in the form of PDE’s and then the similarity variables are translated these equations into the form of ODE’s. The numerical technique named as ‘Adams-Milne Predictor-Corrector method’ is adopted to solve the numerical solutions. The results are examined in the numerical and graphical forms. The graphical behavior of numerous parameters on the velocity, concentration and temperature regions are analyzed. The numerical findings of skin friction and Nusselt number are also placed here and compared the results with the Bvp5c and Adams-Milne (Predictor-Corrector) method. Graphical Abstract: The slip parameter, ratio of relaxation to retardation parameter, viscosity parameter, Deborah number and Hartmann number drops the velocity for both Newtonian and non-Newtonian cases whereas the velocity increases due to the stretching ratio parameter and melting surface coefficient. The heat source/sink parameter, Eckert number, viscosity parameter, thermal conduction coefficient and Hartmann number. The amplification in concentration region is examined by the consideration of Soret number, thermal diffusion and activation energy, while the reaction rate coefficient drops the concentration.

show abstract

Impact of viscous dissipation and coriolis effects in heat and mass transfer analysis of the 3D non-Newtonian fluid flow

Cited by 23 publications

References 42 publications

Effects of Thermal Radiation and Chemical Reaction on Hydromagnetic Fluid Flow in a Cylindrical Collapsible Tube with an Obstacle

Effects of Thermal Radiation and Chemical Reaction on Hydromagnetic Fluid Flow in a Cylindrical Collapsible Tube with an Obstacle

Effect of Viscous Dissipation (<i>Φ</i>) on Temperature Distribution of Blood Plasma in Presence of a Magnetic Field

Stagnation point flow of MHD non-Newtonian fluid and thermal investigation with Joule heating, viscous dissipation and Soret effect

Contact Info

Product

Resources

About

Impact of viscous dissipation and coriolis effects in heat and mass transfer analysis of the 3D non-Newtonian fluid flow

Cited by 23 publications

References 42 publications

Effects of Thermal Radiation and Chemical Reaction on Hydromagnetic Fluid Flow in a Cylindrical Collapsible Tube with an Obstacle

Effects of Thermal Radiation and Chemical Reaction on Hydromagnetic Fluid Flow in a Cylindrical Collapsible Tube with an Obstacle

Effect of Viscous Dissipation (&lt;i&gt;Φ&lt;/i&gt;) on Temperature Distribution of Blood Plasma in Presence of a Magnetic Field

Stagnation point flow of MHD non-Newtonian fluid and thermal investigation with Joule heating, viscous dissipation and Soret effect

Contact Info

Product

Resources

About

Effect of Viscous Dissipation (<i>Φ</i>) on Temperature Distribution of Blood Plasma in Presence of a Magnetic Field