The inclusion of nanoparticles has the potential to improve the thermal efficiency of the base
fl... more The inclusion of nanoparticles has the potential to improve the thermal efficiency of the base fluid. The field of nanofluid (NF) dynamics has attracted important attention due to its extensive range of practical uses like fuel cells, solar energy, medication administration, heat transfer, microfabrication, coolant applications, and other related domains. The aim of this study is to scrutinize the impact of Lorentz force, thermal energy, joule heating, heat source and injection parameters, and Brownian and thermoporetic diffusions on the hybrid nanofluid over the moving wedge. The stability inquiry is reported for the existing work in order to confirm the stable solutions that make the study unique. Novelty of the existing work is to investigate the hybrid nanofluid flow and its stability. The nanoparticles MoS2 and Ag are suspended in ethylene glycol and water used as host fluids. The numerical solution is obtained from the dimensionless first-order differential equations, which are achieved from the basic flow phenomena through similarity alteration variables. The influence of emerging factors on flow phenomena is reported via graphs. The positive eigenvalues report stable solutions, while the negative eigenvalues designate unstable solutions. It is perceived that due to Lorentz force, the rate of the fluid declines while the temperature inside the flow channel enhances. The velocity profile decreases while the temperature and concentration increase with increasing quantities of permeable factors. Similarly, the Forchheimer number causes to enhance the flow rate and decrease the heat and concentration outlines. The current analysis is validated by the published work.
The inclusion of nanoparticles has the potential to improve the thermal efficiency of the base
fl... more The inclusion of nanoparticles has the potential to improve the thermal efficiency of the base fluid. The field of nanofluid (NF) dynamics has attracted important attention due to its extensive range of practical uses like fuel cells, solar energy, medication administration, heat transfer, microfabrication, coolant applications, and other related domains. The aim of this study is to scrutinize the impact of Lorentz force, thermal energy, joule heating, heat source and injection parameters, and Brownian and thermoporetic diffusions on the hybrid nanofluid over the moving wedge. The stability inquiry is reported for the existing work in order to confirm the stable solutions that make the study unique. Novelty of the existing work is to investigate the hybrid nanofluid flow and its stability. The nanoparticles MoS2 and Ag are suspended in ethylene glycol and water used as host fluids. The numerical solution is obtained from the dimensionless first-order differential equations, which are achieved from the basic flow phenomena through similarity alteration variables. The influence of emerging factors on flow phenomena is reported via graphs. The positive eigenvalues report stable solutions, while the negative eigenvalues designate unstable solutions. It is perceived that due to Lorentz force, the rate of the fluid declines while the temperature inside the flow channel enhances. The velocity profile decreases while the temperature and concentration increase with increasing quantities of permeable factors. Similarly, the Forchheimer number causes to enhance the flow rate and decrease the heat and concentration outlines. The current analysis is validated by the published work.
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Papers by Waris Khan
fluid. The field of nanofluid (NF) dynamics has attracted important attention due to its extensive range
of practical uses like fuel cells, solar energy, medication administration, heat transfer, microfabrication,
coolant applications, and other related domains. The aim of this study is to scrutinize the impact of Lorentz
force, thermal energy, joule heating, heat source and injection parameters, and Brownian and thermoporetic
diffusions on the hybrid nanofluid over the moving wedge. The stability inquiry is reported for the existing
work in order to confirm the stable solutions that make the study unique. Novelty of the existing work is
to investigate the hybrid nanofluid flow and its stability. The nanoparticles MoS2 and Ag are suspended in
ethylene glycol and water used as host fluids. The numerical solution is obtained from the dimensionless
first-order differential equations, which are achieved from the basic flow phenomena through similarity
alteration variables. The influence of emerging factors on flow phenomena is reported via graphs. The
positive eigenvalues report stable solutions, while the negative eigenvalues designate unstable solutions.
It is perceived that due to Lorentz force, the rate of the fluid declines while the temperature inside the flow
channel enhances. The velocity profile decreases while the temperature and concentration increase with
increasing quantities of permeable factors. Similarly, the Forchheimer number causes to enhance the flow
rate and decrease the heat and concentration outlines. The current analysis is validated by the published
work.
fluid. The field of nanofluid (NF) dynamics has attracted important attention due to its extensive range
of practical uses like fuel cells, solar energy, medication administration, heat transfer, microfabrication,
coolant applications, and other related domains. The aim of this study is to scrutinize the impact of Lorentz
force, thermal energy, joule heating, heat source and injection parameters, and Brownian and thermoporetic
diffusions on the hybrid nanofluid over the moving wedge. The stability inquiry is reported for the existing
work in order to confirm the stable solutions that make the study unique. Novelty of the existing work is
to investigate the hybrid nanofluid flow and its stability. The nanoparticles MoS2 and Ag are suspended in
ethylene glycol and water used as host fluids. The numerical solution is obtained from the dimensionless
first-order differential equations, which are achieved from the basic flow phenomena through similarity
alteration variables. The influence of emerging factors on flow phenomena is reported via graphs. The
positive eigenvalues report stable solutions, while the negative eigenvalues designate unstable solutions.
It is perceived that due to Lorentz force, the rate of the fluid declines while the temperature inside the flow
channel enhances. The velocity profile decreases while the temperature and concentration increase with
increasing quantities of permeable factors. Similarly, the Forchheimer number causes to enhance the flow
rate and decrease the heat and concentration outlines. The current analysis is validated by the published
work.